This all seems so confusing at first
Write a short description about the course and add a link to your github repository here. This is an R markdown (.Rmd) file so you can use R markdown syntax. See the ‘Useful links’ page in the mooc area (chapter 1) for instructions.
The course is all about exploring the possibilities of ODS and getting familiar with, as well as having fun
I have created an appropriate analysis dataset and excluded unwanted observations. Here we have analysis on the dataset and it’s variables. - Describe your work and results clearly. - Assume the reader has an introductory course level understanding of writing and reading R code as well as statistical methods - Assume the reader has no previous knowledge of your data or the more advanced methods you are using
For these excercises the libraries “dplyr”, “ggplot2” and “GGally” are necessary. When reading the code these need to be installed and read. I have also included cache = F, since without it my version of R refused to knit the plots I made
cache=F
library("dplyr")
##
## Attaching package: 'dplyr'
## The following objects are masked from 'package:stats':
##
## filter, lag
## The following objects are masked from 'package:base':
##
## intersect, setdiff, setequal, union
library("ggplot2")
library("GGally")
##
## Attaching package: 'GGally'
## The following object is masked from 'package:dplyr':
##
## nasa
library("lattice")
Students2014 <- read.table("~/Documents/IODS-project/data/learning2014/learning2014.txt", header = TRUE, sep = " ")
print(Students2014)
## gender Age Attitude deep stra surf Points
## 1 F 53 37 3.583333 3.375 2.583333 25
## 2 M 55 31 2.916667 2.750 3.166667 12
## 3 F 49 25 3.500000 3.625 2.250000 24
## 4 M 53 35 3.500000 3.125 2.250000 10
## 5 M 49 37 3.666667 3.625 2.833333 22
## 6 F 38 38 4.750000 3.625 2.416667 21
## 7 M 50 35 3.833333 2.250 1.916667 21
## 8 F 37 29 3.250000 4.000 2.833333 31
## 9 M 37 38 4.333333 4.250 2.166667 24
## 10 F 42 21 4.000000 3.500 3.000000 26
## 11 M 37 39 3.583333 3.625 2.666667 31
## 12 F 34 38 3.833333 4.750 2.416667 31
## 13 F 34 24 4.250000 3.625 2.250000 23
## 14 F 34 30 3.333333 3.500 2.750000 25
## 15 M 35 26 4.166667 1.750 2.333333 21
## 16 F 33 41 3.666667 3.875 2.333333 31
## 17 F 32 26 4.083333 1.375 2.916667 20
## 18 F 44 26 3.500000 3.250 2.500000 22
## 19 M 29 17 4.083333 3.000 3.750000 9
## 20 F 30 27 4.000000 3.750 2.750000 24
## 21 M 27 39 3.916667 2.625 2.333333 28
## 22 M 29 34 4.000000 2.375 2.416667 30
## 23 F 31 27 4.000000 3.625 3.000000 24
## 24 F 37 23 3.666667 2.750 2.416667 9
## 25 F 26 37 3.666667 1.750 2.833333 26
## 26 F 26 44 4.416667 3.250 3.166667 32
## 27 M 30 41 3.916667 4.000 3.000000 32
## 28 F 33 37 3.750000 3.625 2.000000 33
## 29 F 33 25 3.250000 2.875 3.500000 29
## 30 M 28 30 3.583333 3.000 3.750000 30
## 31 M 26 34 4.916667 1.625 2.500000 19
## 32 F 27 32 3.583333 3.250 2.083333 23
## 33 F 25 20 2.916667 3.500 2.416667 19
## 34 F 31 24 3.666667 3.000 2.583333 12
## 35 M 20 42 4.500000 3.250 1.583333 10
## 36 F 39 16 4.083333 1.875 2.833333 11
## 37 M 38 31 3.833333 4.375 1.833333 20
## 38 M 24 38 3.250000 3.625 2.416667 26
## 39 M 26 38 2.333333 2.500 3.250000 31
## 40 M 25 33 3.333333 1.250 3.416667 20
## 41 F 30 17 4.083333 4.000 3.416667 23
## 42 F 25 25 2.916667 3.000 3.166667 12
## 43 M 30 32 3.333333 2.500 3.500000 24
## 44 F 48 35 3.833333 4.875 2.666667 17
## 45 F 24 32 3.666667 5.000 2.416667 29
## 46 F 40 42 4.666667 4.375 3.583333 23
## 47 M 25 31 3.750000 3.250 2.083333 28
## 48 F 23 39 3.416667 4.000 3.750000 31
## 49 F 25 19 4.166667 3.125 2.916667 23
## 50 F 23 21 2.916667 2.500 2.916667 25
## 51 M 27 25 4.166667 3.125 2.416667 18
## 52 M 25 32 3.583333 3.250 3.000000 19
## 53 M 23 32 2.833333 2.125 3.416667 22
## 54 F 23 26 4.000000 2.750 2.916667 25
## 55 F 23 23 2.916667 2.375 3.250000 21
## 56 F 45 38 3.000000 3.125 3.250000 9
## 57 F 22 28 4.083333 4.000 2.333333 28
## 58 F 23 33 2.916667 4.000 3.250000 25
## 59 M 21 48 3.500000 2.250 2.500000 29
## 60 M 21 40 4.333333 3.250 1.750000 33
## 61 F 21 40 4.250000 3.625 2.250000 33
## 62 F 21 47 3.416667 3.625 2.083333 25
## 63 F 26 23 3.083333 2.500 2.833333 18
## 64 F 25 31 4.583333 1.875 2.833333 22
## 65 F 26 27 3.416667 2.000 2.416667 17
## 66 M 21 41 3.416667 1.875 2.250000 25
## 67 F 23 34 3.416667 4.000 2.833333 28
## 68 F 22 25 3.583333 2.875 2.250000 22
## 69 F 22 21 1.583333 3.875 1.833333 26
## 70 F 22 14 3.333333 2.500 2.916667 11
## 71 F 23 19 4.333333 2.750 2.916667 29
## 72 M 22 37 4.416667 4.500 2.083333 22
## 73 M 23 32 4.833333 3.375 2.333333 21
## 74 M 24 28 3.083333 2.625 2.416667 28
## 75 F 22 41 3.000000 4.125 2.750000 33
## 76 F 23 25 4.083333 2.625 3.250000 16
## 77 M 22 28 4.083333 2.250 1.750000 31
## 78 M 20 38 3.750000 2.750 2.583333 22
## 79 M 22 31 3.083333 3.000 3.333333 31
## 80 M 21 35 4.750000 1.625 2.833333 23
## 81 F 22 36 4.250000 1.875 2.500000 26
## 82 F 23 26 4.166667 3.375 2.416667 12
## 83 M 21 44 4.416667 3.750 2.416667 26
## 84 M 22 45 3.833333 2.125 2.583333 31
## 85 M 29 32 3.333333 2.375 3.000000 19
## 86 F 29 39 3.166667 2.750 2.000000 30
## 87 F 21 25 3.166667 3.125 3.416667 12
## 88 M 28 33 3.833333 3.500 2.833333 17
## 89 F 21 33 4.250000 2.625 2.250000 18
## 90 F 30 30 3.833333 3.375 2.750000 19
## 91 F 21 29 3.666667 2.250 3.916667 21
## 92 M 23 33 3.833333 3.000 2.333333 24
## 93 F 21 33 3.833333 4.000 2.750000 28
## 94 F 21 35 3.833333 3.500 2.750000 17
## 95 F 20 36 3.666667 2.625 2.916667 18
## 96 M 22 37 4.333333 2.500 2.083333 17
## 97 M 21 42 3.750000 3.750 3.666667 23
## 98 M 21 32 4.166667 3.625 2.833333 26
## 99 F 20 50 4.000000 4.125 3.416667 28
## 100 M 22 47 4.000000 4.375 1.583333 31
## 101 F 20 36 4.583333 2.625 2.916667 27
## 102 F 20 36 3.666667 4.000 3.000000 25
## 103 M 24 29 3.666667 2.750 2.916667 23
## 104 F 20 35 3.833333 2.750 2.666667 21
## 105 F 19 40 2.583333 1.375 3.000000 27
## 106 F 21 35 3.500000 2.250 2.750000 28
## 107 F 21 32 3.083333 3.625 3.083333 23
## 108 F 22 26 4.250000 3.750 2.500000 21
## 109 F 25 20 3.166667 4.000 2.333333 25
## 110 F 21 27 3.083333 3.125 3.000000 11
## 111 F 22 32 4.166667 3.250 3.000000 19
## 112 F 25 33 2.250000 2.125 4.000000 24
## 113 F 20 39 3.333333 2.875 3.250000 28
## 114 M 24 33 3.083333 1.500 3.500000 21
## 115 F 20 30 2.750000 2.500 3.500000 24
## 116 M 21 37 3.250000 3.250 3.833333 24
## 117 F 20 25 4.000000 3.625 2.916667 20
## 118 F 20 29 3.583333 3.875 2.166667 19
## 119 M 31 39 4.083333 3.875 1.666667 30
## 120 F 20 36 4.250000 2.375 2.083333 22
## 121 F 22 29 3.416667 3.000 2.833333 16
## 122 F 22 21 3.083333 3.375 3.416667 16
## 123 M 21 31 3.500000 2.750 3.333333 19
## 124 M 22 40 3.666667 4.500 2.583333 30
## 125 F 21 31 4.250000 2.625 2.833333 23
## 126 F 21 23 4.250000 2.750 3.333333 19
## 127 F 21 28 3.833333 3.250 3.000000 18
## 128 F 21 37 4.416667 4.125 2.583333 28
## 129 F 20 26 3.500000 3.375 2.416667 21
## 130 F 21 24 3.583333 2.750 3.583333 19
## 131 F 25 30 3.666667 4.125 2.083333 27
## 132 M 21 28 2.083333 3.250 4.333333 24
## 133 F 24 29 4.250000 2.875 2.666667 21
## 134 F 20 24 3.583333 2.875 3.000000 20
## 135 M 21 31 4.000000 2.375 2.666667 28
## 136 F 20 19 3.333333 3.875 2.166667 12
## 137 F 20 20 3.500000 2.125 2.666667 21
## 138 F 18 38 3.166667 4.000 2.250000 28
## 139 F 21 34 3.583333 3.250 2.666667 31
## 140 F 19 37 3.416667 2.625 3.333333 18
## 141 F 21 29 4.250000 2.750 3.500000 25
## 142 F 20 23 3.250000 4.000 2.750000 19
## 143 M 21 41 4.416667 3.000 2.000000 21
## 144 F 20 27 3.250000 3.375 2.833333 16
## 145 F 21 35 3.916667 3.875 3.500000 7
## 146 F 20 34 3.583333 3.250 2.500000 21
## 147 F 18 32 4.500000 3.375 3.166667 17
## 148 M 22 33 3.583333 4.125 3.083333 22
## 149 F 22 33 3.666667 3.500 2.916667 18
## 150 M 24 35 2.583333 2.000 3.166667 25
## 151 F 19 32 4.166667 3.625 2.500000 24
## 152 F 20 31 3.250000 3.375 3.833333 23
## 153 F 20 28 4.333333 2.125 2.250000 23
## 154 F 17 17 3.916667 4.625 3.416667 26
## 155 M 19 19 2.666667 2.500 3.750000 12
## 156 F 20 35 3.083333 2.875 3.000000 32
## 157 F 20 24 3.750000 2.750 2.583333 22
## 158 F 20 21 4.166667 4.000 3.333333 20
## 159 F 20 29 4.166667 2.375 2.833333 21
## 160 F 19 19 3.250000 3.875 3.000000 23
## 161 F 19 20 4.083333 3.375 2.833333 20
## 162 F 22 42 2.916667 1.750 3.166667 28
## 163 M 35 41 3.833333 3.000 2.750000 31
## 164 F 18 37 3.166667 2.625 3.416667 18
## 165 F 19 36 3.416667 2.625 3.000000 30
## 166 M 21 18 4.083333 3.375 2.666667 19
#2.
dim(Students2014)
## [1] 166 7
str(Students2014)
## 'data.frame': 166 obs. of 7 variables:
## $ gender : Factor w/ 2 levels "F","M": 1 2 1 2 2 1 2 1 2 1 ...
## $ Age : int 53 55 49 53 49 38 50 37 37 42 ...
## $ Attitude: int 37 31 25 35 37 38 35 29 38 21 ...
## $ deep : num 3.58 2.92 3.5 3.5 3.67 ...
## $ stra : num 3.38 2.75 3.62 3.12 3.62 ...
## $ surf : num 2.58 3.17 2.25 2.25 2.83 ...
## $ Points : int 25 12 24 10 22 21 21 31 24 26 ...
Second we display graphical implementation of the data
Overview:
plot(Students2014)
Results without variable ‘gender’: pairs(Students2014[-1])
pairs(Students2014[-1])
Last, a ggpairs-graphic for possibly a more clear display:
ggpairs(Students2014, mapping = aes(col = gender, alpha = 0.3), lower = list(combo = wrap("facethist", bins = 20)))
Next we have summaries for the included variables and scatterplots to clarify their influence on the ‘points’ -variable:
library(ggplot2)
qplot(Attitude, Points, data = Students2014) + geom_smooth(method = "lm")
qplot(Age, Points, data = Students2014) + geom_smooth(method = "lm")
qplot(gender, Points, data = Students2014) + geom_smooth(method = "lm")
qplot(deep, Points, data = Students2014) + geom_smooth(method = "lm")
qplot(stra, Points, data = Students2014) + geom_smooth(method = "lm")
qplot(surf, Points, data = Students2014) + geom_smooth(method = "lm")
Next some more illustration of the effects of the other variables to the ‘points’-variable and summaries of these
M_Attitude <- lm(Points ~ Attitude, data = Students2014)
summary(M_Attitude)
##
## Call:
## lm(formula = Points ~ Attitude, data = Students2014)
##
## Residuals:
## Min 1Q Median 3Q Max
## -16.9763 -3.2119 0.4339 4.1534 10.6645
##
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 11.63715 1.83035 6.358 1.95e-09 ***
## Attitude 0.35255 0.05674 6.214 4.12e-09 ***
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## Residual standard error: 5.32 on 164 degrees of freedom
## Multiple R-squared: 0.1906, Adjusted R-squared: 0.1856
## F-statistic: 38.61 on 1 and 164 DF, p-value: 4.119e-09
M_Age <- lm(Points ~ Age, data = Students2014)
summary(M_Age)
##
## Call:
## lm(formula = Points ~ Age, data = Students2014)
##
## Residuals:
## Min 1Q Median 3Q Max
## -16.0360 -3.7531 0.0958 4.6762 10.8128
##
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 24.52150 1.57339 15.585 <2e-16 ***
## Age -0.07074 0.05901 -1.199 0.232
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## Residual standard error: 5.887 on 164 degrees of freedom
## Multiple R-squared: 0.008684, Adjusted R-squared: 0.00264
## F-statistic: 1.437 on 1 and 164 DF, p-value: 0.2324
M_gender <- lm(Points ~ gender, data = Students2014)
summary(M_gender)
##
## Call:
## lm(formula = Points ~ gender, data = Students2014)
##
## Residuals:
## Min 1Q Median 3Q Max
## -15.3273 -3.3273 0.5179 4.5179 10.6727
##
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 22.3273 0.5613 39.776 <2e-16 ***
## genderM 1.1549 0.9664 1.195 0.234
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## Residual standard error: 5.887 on 164 degrees of freedom
## Multiple R-squared: 0.008632, Adjusted R-squared: 0.002587
## F-statistic: 1.428 on 1 and 164 DF, p-value: 0.2338
M_deep <- lm(Points ~ deep, data = Students2014)
summary(M_deep)
##
## Call:
## lm(formula = Points ~ deep, data = Students2014)
##
## Residuals:
## Min 1Q Median 3Q Max
## -15.6913 -3.6935 0.2862 4.9957 10.3537
##
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 23.1141 3.0908 7.478 4.31e-12 ***
## deep -0.1080 0.8306 -0.130 0.897
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## Residual standard error: 5.913 on 164 degrees of freedom
## Multiple R-squared: 0.000103, Adjusted R-squared: -0.005994
## F-statistic: 0.01689 on 1 and 164 DF, p-value: 0.8967
M_stra <- lm(Points ~ stra, data = Students2014)
summary(M_stra)
##
## Call:
## lm(formula = Points ~ stra, data = Students2014)
##
## Residuals:
## Min 1Q Median 3Q Max
## -16.5581 -3.8198 0.1042 4.3024 10.1394
##
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 19.233 1.897 10.141 <2e-16 ***
## stra 1.116 0.590 1.892 0.0603 .
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## Residual standard error: 5.849 on 164 degrees of freedom
## Multiple R-squared: 0.02135, Adjusted R-squared: 0.01538
## F-statistic: 3.578 on 1 and 164 DF, p-value: 0.06031
M_surf <- lm(Points ~ surf, data = Students2014)
summary(M_surf)
##
## Call:
## lm(formula = Points ~ surf, data = Students2014)
##
## Residuals:
## Min 1Q Median 3Q Max
## -14.6539 -3.3744 0.3574 4.4734 10.2234
##
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 27.2017 2.4432 11.134 <2e-16 ***
## surf -1.6091 0.8613 -1.868 0.0635 .
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## Residual standard error: 5.851 on 164 degrees of freedom
## Multiple R-squared: 0.02084, Adjusted R-squared: 0.01487
## F-statistic: 3.49 on 1 and 164 DF, p-value: 0.06351
Looking at the output of the summaries, the most trustworthy explanatory variables are Attitude, Age, surf and stra. These are confirmed by the scatterplots of the individual dependences of points on the other variables. Age, Attitude and stra can be seen to probably have influence on points. The values of the regression make these assumption reasonable, with a quite low margin for failure. (Failure in this case means selecting output or in other words a random sample where the assumptions fail to reflect or descibe the truth/dependence of the variables).
The mean, standard error and variance for the dataset’s variables:
sapply(Students2014, mean, na.rm = TRUE)
## Warning in mean.default(X[[i]], ...): argument is not numeric or logical:
## returning NA
## gender Age Attitude deep stra surf Points
## NA 25.512048 31.427711 3.679719 3.121235 2.787149 22.716867
sapply(Students2014, sd, na.rm = TRUE)
## Warning in var(if (is.vector(x) || is.factor(x)) x else as.double(x), na.rm = na.rm): Calling var(x) on a factor x is deprecated and will become an error.
## Use something like 'all(duplicated(x)[-1L])' to test for a constant vector.
## gender Age Attitude deep stra surf Points
## 0.4742358 7.7660785 7.2990794 0.5541369 0.7718318 0.5288405 5.8948836
sapply(Students2014, var, na.rm = TRUE)
## Warning in FUN(X[[i]], ...): Calling var(x) on a factor x is deprecated and will become an error.
## Use something like 'all(duplicated(x)[-1L])' to test for a constant vector.
## gender Age Attitude deep stra surf
## 0.2248996 60.3119752 53.2765608 0.3070677 0.5957244 0.2796722
## Points
## 34.7496532
Below is a regression model where exam points is the target/dependent variable, with three explanatory variables. These explanatory variables were chosen because it can be seen that they correlate with the variable that we are attempting to explain (points). At the same time the model is drawn in several different ways to help interpret and understand it’s relevance.
Model3 <- lm(formula = Points ~ Attitude + Age + stra, data = Students2014)
plot(Model3)
The following functions work in my R-project, but for some reason they refused to knit to HTML. I have taken measures to enable the knitting of error terms etc, and it still won’t work. (I used these functions to make some interesting plots that I discuss later in the exercise. These were not individually necessary for ch2, and I have provided a collection of the mentioned plots in an other way also. This collection is included in the code). Still, I wanted to post them here to show what I did in another way. Readers please note: These were not as such demanded, and are provided in the necessary form later. If experimentation is done on them, I recommend copying them to an R-document, along with all the other necessary elements
r.squared(Model3, model = NULL, type = c(“Attitude”, “Age”, “stra”), dfcor = TRUE) #Normal Q-Q r.squared(Model3, model = NULL, type = c(“Attitude”, “Age”, “stra”), dfcor = FALSE) r.squared(Model3, model = “lm”, type = c(“Attitude”, “Age”, “stra”), dfcor = TRUE) #Res vs Lev r.squared(Model3, model = “lm”, type = c(“Attitude”, “Age”, “stra”), dfcor = FALSE) #Res vs Fit
summary(Model3)
##
## Call:
## lm(formula = Points ~ Attitude + Age + stra, data = Students2014)
##
## Residuals:
## Min 1Q Median 3Q Max
## -18.1149 -3.2003 0.3303 3.4129 10.7599
##
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 10.89543 2.64834 4.114 6.17e-05 ***
## Attitude 0.34808 0.05622 6.191 4.72e-09 ***
## Age -0.08822 0.05302 -1.664 0.0981 .
## stra 1.00371 0.53434 1.878 0.0621 .
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## Residual standard error: 5.26 on 162 degrees of freedom
## Multiple R-squared: 0.2182, Adjusted R-squared: 0.2037
## F-statistic: 15.07 on 3 and 162 DF, p-value: 1.07e-08
The summary provides seemingly significant results, with considerably high correlation to points of all the other variables. The error has remained quite low in relation to the amount of variables used. The r-squared shows generally how close the data on the variables is to the regression line. Experimenting with different inputs to the function r-squared 4 different but interesting outputs can be found with this ampunt of experimentation. It seems that the Multiple R^2 is quite low, so it’s not too significant (It doesn’t deny the validity of the regression. The variants of the r-squared functions produced the Residuals vs Fitted, Residuals vs Leverage, and Normal Q-Q plots, as well as Scale location.
par(mfrow = c(2,2))
plot(Model3, which = c(1,2,5))
Linear regression models have a few general assumtions: 1. Linearity 2. The errors of the model are normally distributed. 2. The errors are not correlated. 3. The sizes of the errors do not depend on the variables used to explain the target variable.
Now let’s think how the plots produced correspond (or not) to these assumption:
The Q–Q-plot demonstrates how the standardised residuals of the model fit to the theory or reasoning behind the model. Therefore the normal distribution assumption seems to be true for the model.
The residuals vs. fitted values -plot does not seem to be regular/subjected to any pattern, meaning that the errors are not correlated to the explanatory variables and their size is independent.
Therefore all of the assumptions are valid for the model created.
There was a problem reading the file into R from my computer; The code worked but the data didn’t print out correctly, even though the same exact code combinations worked elsewhere, so I have included the necessary parts of the wrangling part to create the dataset again.
cache=F
library(tidyr)
library(dplyr)
library(ggplot2)
library(gmodels)
student_mat <- read.csv("~/Documents/IODS-project/data/student-mat.csv", sep = ";")
student_por <- read.csv("~/Documents/IODS-project/data/student-por.csv", sep = ";")
join_by <- c("school","sex","age","address","famsize","Pstatus","Medu","Fedu","Mjob","Fjob","reason","nursery","internet")
math_por <- inner_join(student_mat, student_por, by = join_by, suffix = c(".student_mat", ".student_por"))
alc <- select(math_por, one_of(join_by))
notjoined_columns <- colnames(student_mat)[!colnames(student_mat) %in% join_by]
# for every column name not used for joining...
for(column_name in notjoined_columns) {
# select two columns from 'math_por' with the same original name
two_columns <- select(math_por, starts_with(column_name))
# select the first column vector of those two columns
first_column <- select(two_columns, 1)[[1]]
# if that first column vector is numeric...
if(is.numeric(first_column)) {
# take a rounded average of each row of the two columns and
# add the resulting vector to the alc data frame
alc[column_name] <- round(rowMeans(two_columns))
} else { # else if it's not numeric...
# add the first column vector to the alc data frame
alc[column_name] <- first_column
}
}
alc <- mutate(alc, alc_use = (Dalc + Walc) / 2)
alc <- mutate(alc, high_use = alc_use > 2)
#alc <- read.csv("~/Documents/IODS-project/data/create_alc.R", row.names = NULL)
names(alc)
## [1] "school" "sex" "age" "address" "famsize"
## [6] "Pstatus" "Medu" "Fedu" "Mjob" "Fjob"
## [11] "reason" "nursery" "internet" "guardian" "traveltime"
## [16] "studytime" "failures" "schoolsup" "famsup" "paid"
## [21] "activities" "higher" "romantic" "famrel" "freetime"
## [26] "goout" "Dalc" "Walc" "health" "absences"
## [31] "G1" "G2" "G3" "alc_use" "high_use"
For my variables, I chose sex, final exam scores, famsize and studytime. My hypotheses are as follows: Fewer females than males who took part consume a lot of alcohol. I would also assume that a person who doesn’t consume a lot of alcohol gets better grades than someone who drinks more.
Now we must test the hypothesis.
alc %>% group_by(sex, high_use) %>%summarise(count=n(),mean_grade=mean(G3))
## # A tibble: 4 x 4
## # Groups: sex [?]
## sex high_use count mean_grade
## <fct> <lgl> <int> <dbl>
## 1 F FALSE 156 11.4
## 2 F TRUE 42 11.7
## 3 M FALSE 112 12.2
## 4 M TRUE 72 10.3
First we have the crosstabulation for alcohol usage, sex and the average of the final exam grades. The results of this tabulation tell us two things: i.) A higher percentage of men than women use alcohol a lot. ii.) Interestingly, those women who drink more have slightly higher grades. In contrast, binge-drinking men have worse grades than those who don’t drink a lot.
Then let’s create a boxplot of high alcohol usages effects to the final grades.
g1 <- ggplot(alc, aes(x= high_use, y=G3), col=sex)
g1 + geom_boxplot()+ylab("grade")
It is clear that on average, alcohol-lovers have worse grades than moderate drinkers.
Then we have a barplot describing the relationship; alcohol usage vs. study time. Those who do not drink much are included in the darkred bar and those who drink a lot in the darkblue bar.
counts <- table(alc$high_use, alc$studytime)
barplot(counts, main = "Usage of alcohol", xlab = "studytime", col = c("darkred", "darkblue"), beside = TRUE)
The key ratio described is the share of the drinkaholics in each category of study time. The shares are about equally small in 4 and 3 but get bigger in 2 and in 1 it is almost as common to drink a lot than not to drink a lot.
Then we compare alcohol usage to family size.
counts2 <- table(alc$high_use, alc$famsize)
barplot(counts2, main = "Usage of alcohol", xlab = "famsize", col = c("black", "gold"), beside = TRUE)
The result is that students from small families, are somewhat more likely to drink a lot than those from big families.
m <- glm(high_use ~ famsize + sex + G3 + studytime, data = alc, family = "binomial")
summary(m)
##
## Call:
## glm(formula = high_use ~ famsize + sex + G3 + studytime, family = "binomial",
## data = alc)
##
## Deviance Residuals:
## Min 1Q Median 3Q Max
## -1.4556 -0.8448 -0.6728 1.1674 2.1425
##
## Coefficients:
## Estimate Std. Error z value Pr(>|z|)
## (Intercept) 0.36140 0.50827 0.711 0.47706
## famsizeLE3 0.31601 0.25722 1.229 0.21923
## sexM 0.67284 0.24445 2.752 0.00592 **
## G3 -0.07463 0.03598 -2.074 0.03806 *
## studytime -0.41808 0.15933 -2.624 0.00869 **
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## (Dispersion parameter for binomial family taken to be 1)
##
## Null deviance: 465.68 on 381 degrees of freedom
## Residual deviance: 435.28 on 377 degrees of freedom
## AIC: 445.28
##
## Number of Fisher Scoring iterations: 4
Coefficients as odds ratios:
OR <- coef(m) %>% exp
OR
## (Intercept) famsizeLE3 sexM G3 studytime
## 1.4353404 1.3716456 1.9598015 0.9280889 0.6583124
COnfidence intervals:
CI <- confint(m) %>% exp
## Waiting for profiling to be done...
CI
## 2.5 % 97.5 %
## (Intercept) 0.5317356 3.9213022
## famsizeLE3 0.8244681 2.2647911
## sexM 1.2165115 3.1774177
## G3 0.8641265 0.9954148
## studytime 0.4773416 0.8930376
m <- glm(high_use ~ sex + studytime, data = alc, family = "binomial")
probabilities <- predict(m, type = "response")
alc <- mutate(alc, probability = probabilities)
alc <- mutate(alc, prediction = probability > 0.3)
select(alc, studytime, sex, high_use, probability, prediction) %>% tail(10)
## studytime sex high_use probability prediction
## 373 1 M FALSE 0.4795667 TRUE
## 374 1 M TRUE 0.4795667 TRUE
## 375 3 F FALSE 0.1536065 FALSE
## 376 1 F FALSE 0.3222140 TRUE
## 377 3 F FALSE 0.1536065 FALSE
## 378 2 F FALSE 0.2270396 FALSE
## 379 2 F FALSE 0.2270396 FALSE
## 380 2 F FALSE 0.2270396 FALSE
## 381 1 M TRUE 0.4795667 TRUE
## 382 1 M TRUE 0.4795667 TRUE
table(high_use = alc$high_use, prediction = alc$prediction)
## prediction
## high_use FALSE TRUE
## FALSE 158 110
## TRUE 37 77
CrossTable(alc$high_use, alc$prediction)
##
##
## Cell Contents
## |-------------------------|
## | N |
## | Chi-square contribution |
## | N / Row Total |
## | N / Col Total |
## | N / Table Total |
## |-------------------------|
##
##
## Total Observations in Table: 382
##
##
## | alc$prediction
## alc$high_use | FALSE | TRUE | Row Total |
## -------------|-----------|-----------|-----------|
## FALSE | 158 | 110 | 268 |
## | 3.283 | 3.424 | |
## | 0.590 | 0.410 | 0.702 |
## | 0.810 | 0.588 | |
## | 0.414 | 0.288 | |
## -------------|-----------|-----------|-----------|
## TRUE | 37 | 77 | 114 |
## | 7.719 | 8.049 | |
## | 0.325 | 0.675 | 0.298 |
## | 0.190 | 0.412 | |
## | 0.097 | 0.202 | |
## -------------|-----------|-----------|-----------|
## Column Total | 195 | 187 | 382 |
## | 0.510 | 0.490 | |
## -------------|-----------|-----------|-----------|
##
##
counts3 <- table(alc$high_use, alc$prediction)
barplot(counts3, main = "Usage of alcohol", xlab = "high_use", col = c("pink", "purple"), beside = TRUE)
g <- ggplot(alc, aes(x = probability, y = high_use, col = prediction))
g + geom_point()
table(high_use = alc$high_use, prediction = alc$prediction) %>% prop.table %>% addmargins
## prediction
## high_use FALSE TRUE Sum
## FALSE 0.41361257 0.28795812 0.70157068
## TRUE 0.09685864 0.20157068 0.29842932
## Sum 0.51047120 0.48952880 1.00000000
loss_func <- function(class, prob) {
n_wrong <- abs(class - prob) > 0.5
mean(n_wrong)
}
loss_func(class = alc$high_use, prob = 0)
## [1] 0.2984293
According to the results, the model provided provides a sense of reality, even if it it statistically not very reliable. By simply guessing what the results would be, the ideas that one comes up with could be similar but more accurate. What the model probably works for though, is that is offers some slight validation for any guesses made. Not much can be concluded from the model alone however, since the ratio of wrong predictions is quite large.
library(boot)
##
## Attaching package: 'boot'
## The following object is masked from 'package:lattice':
##
## melanoma
cv <- cv.glm(data = alc, cost = loss_func, glmfit = m, K = 10)
cv$delta[1]
## [1] 0.3062827
n <- glm(high_use ~ sex + studytime + famsize + failures + activities + absences, data = alc, family = "binomial")
probabilities <- predict(n, type = "response")
select(alc, studytime, sex, high_use, probability, prediction) %>% tail(10)
## studytime sex high_use probability prediction
## 373 1 M FALSE 0.4795667 TRUE
## 374 1 M TRUE 0.4795667 TRUE
## 375 3 F FALSE 0.1536065 FALSE
## 376 1 F FALSE 0.3222140 TRUE
## 377 3 F FALSE 0.1536065 FALSE
## 378 2 F FALSE 0.2270396 FALSE
## 379 2 F FALSE 0.2270396 FALSE
## 380 2 F FALSE 0.2270396 FALSE
## 381 1 M TRUE 0.4795667 TRUE
## 382 1 M TRUE 0.4795667 TRUE
table(high_use = alc$high_use, prediction = alc$prediction)
## prediction
## high_use FALSE TRUE
## FALSE 158 110
## TRUE 37 77
CrossTable(alc$high_use, alc$prediction)
##
##
## Cell Contents
## |-------------------------|
## | N |
## | Chi-square contribution |
## | N / Row Total |
## | N / Col Total |
## | N / Table Total |
## |-------------------------|
##
##
## Total Observations in Table: 382
##
##
## | alc$prediction
## alc$high_use | FALSE | TRUE | Row Total |
## -------------|-----------|-----------|-----------|
## FALSE | 158 | 110 | 268 |
## | 3.283 | 3.424 | |
## | 0.590 | 0.410 | 0.702 |
## | 0.810 | 0.588 | |
## | 0.414 | 0.288 | |
## -------------|-----------|-----------|-----------|
## TRUE | 37 | 77 | 114 |
## | 7.719 | 8.049 | |
## | 0.325 | 0.675 | 0.298 |
## | 0.190 | 0.412 | |
## | 0.097 | 0.202 | |
## -------------|-----------|-----------|-----------|
## Column Total | 195 | 187 | 382 |
## | 0.510 | 0.490 | |
## -------------|-----------|-----------|-----------|
##
##
g <- ggplot(alc, aes(x = probability, y = high_use, col = prediction))
g + geom_point()
table(high_use = alc$high_use, prediction = alc$prediction) %>% prop.table %>% addmargins
## prediction
## high_use FALSE TRUE Sum
## FALSE 0.41361257 0.28795812 0.70157068
## TRUE 0.09685864 0.20157068 0.29842932
## Sum 0.51047120 0.48952880 1.00000000
loss_func <- function(class, prob) {
n_wrong <- abs(class - prob) > 0.5
mean(n_wrong)
}
loss_func(class = alc$high_use, prob = 0)
## [1] 0.2984293
cv <- cv.glm(data = alc, cost = loss_func, glmfit = m, K = 10)
cv$delta[1]
## [1] 0.3403141
o <- glm(high_use ~ sex + studytime + famsize + failures + activities + absences + health + goout + freetime + romantic, data = alc, family = "binomial")
probabilities <- predict(o, type = "response")
select(alc, studytime, sex, high_use, probability, prediction) %>% tail(10)
## studytime sex high_use probability prediction
## 373 1 M FALSE 0.4795667 TRUE
## 374 1 M TRUE 0.4795667 TRUE
## 375 3 F FALSE 0.1536065 FALSE
## 376 1 F FALSE 0.3222140 TRUE
## 377 3 F FALSE 0.1536065 FALSE
## 378 2 F FALSE 0.2270396 FALSE
## 379 2 F FALSE 0.2270396 FALSE
## 380 2 F FALSE 0.2270396 FALSE
## 381 1 M TRUE 0.4795667 TRUE
## 382 1 M TRUE 0.4795667 TRUE
table(high_use = alc$high_use, prediction = alc$prediction)
## prediction
## high_use FALSE TRUE
## FALSE 158 110
## TRUE 37 77
CrossTable(alc$high_use, alc$prediction)
##
##
## Cell Contents
## |-------------------------|
## | N |
## | Chi-square contribution |
## | N / Row Total |
## | N / Col Total |
## | N / Table Total |
## |-------------------------|
##
##
## Total Observations in Table: 382
##
##
## | alc$prediction
## alc$high_use | FALSE | TRUE | Row Total |
## -------------|-----------|-----------|-----------|
## FALSE | 158 | 110 | 268 |
## | 3.283 | 3.424 | |
## | 0.590 | 0.410 | 0.702 |
## | 0.810 | 0.588 | |
## | 0.414 | 0.288 | |
## -------------|-----------|-----------|-----------|
## TRUE | 37 | 77 | 114 |
## | 7.719 | 8.049 | |
## | 0.325 | 0.675 | 0.298 |
## | 0.190 | 0.412 | |
## | 0.097 | 0.202 | |
## -------------|-----------|-----------|-----------|
## Column Total | 195 | 187 | 382 |
## | 0.510 | 0.490 | |
## -------------|-----------|-----------|-----------|
##
##
g <- ggplot(alc, aes(x = probability, y = high_use, col = prediction))
g + geom_point()
table(high_use = alc$high_use, prediction = alc$prediction) %>% prop.table %>% addmargins
## prediction
## high_use FALSE TRUE Sum
## FALSE 0.41361257 0.28795812 0.70157068
## TRUE 0.09685864 0.20157068 0.29842932
## Sum 0.51047120 0.48952880 1.00000000
loss_func <- function(class, prob) {
n_wrong <- abs(class - prob) > 0.5
mean(n_wrong)
}
loss_func(class = alc$high_use, prob = 0)
## [1] 0.2984293
cv <- cv.glm(data = alc, cost = loss_func, glmfit = m, K = 10)
cv$delta[1]
## [1] 0.3141361
p <- glm(high_use ~ failures + activities + absences + health + goout + freetime + romantic, data = alc, family = "binomial")
probabilities <- predict(p, type = "response")
select(alc, studytime, sex, high_use, probability, prediction) %>% tail(10)
## studytime sex high_use probability prediction
## 373 1 M FALSE 0.4795667 TRUE
## 374 1 M TRUE 0.4795667 TRUE
## 375 3 F FALSE 0.1536065 FALSE
## 376 1 F FALSE 0.3222140 TRUE
## 377 3 F FALSE 0.1536065 FALSE
## 378 2 F FALSE 0.2270396 FALSE
## 379 2 F FALSE 0.2270396 FALSE
## 380 2 F FALSE 0.2270396 FALSE
## 381 1 M TRUE 0.4795667 TRUE
## 382 1 M TRUE 0.4795667 TRUE
table(high_use = alc$high_use, prediction = alc$prediction)
## prediction
## high_use FALSE TRUE
## FALSE 158 110
## TRUE 37 77
CrossTable(alc$high_use, alc$prediction)
##
##
## Cell Contents
## |-------------------------|
## | N |
## | Chi-square contribution |
## | N / Row Total |
## | N / Col Total |
## | N / Table Total |
## |-------------------------|
##
##
## Total Observations in Table: 382
##
##
## | alc$prediction
## alc$high_use | FALSE | TRUE | Row Total |
## -------------|-----------|-----------|-----------|
## FALSE | 158 | 110 | 268 |
## | 3.283 | 3.424 | |
## | 0.590 | 0.410 | 0.702 |
## | 0.810 | 0.588 | |
## | 0.414 | 0.288 | |
## -------------|-----------|-----------|-----------|
## TRUE | 37 | 77 | 114 |
## | 7.719 | 8.049 | |
## | 0.325 | 0.675 | 0.298 |
## | 0.190 | 0.412 | |
## | 0.097 | 0.202 | |
## -------------|-----------|-----------|-----------|
## Column Total | 195 | 187 | 382 |
## | 0.510 | 0.490 | |
## -------------|-----------|-----------|-----------|
##
##
g <- ggplot(alc, aes(x = probability, y = high_use, col = prediction))
g + geom_point()
table(high_use = alc$high_use, prediction = alc$prediction) %>% prop.table %>% addmargins
## prediction
## high_use FALSE TRUE Sum
## FALSE 0.41361257 0.28795812 0.70157068
## TRUE 0.09685864 0.20157068 0.29842932
## Sum 0.51047120 0.48952880 1.00000000
loss_func <- function(class, prob) {
n_wrong <- abs(class - prob) > 0.5
mean(n_wrong)
}
loss_func(class = alc$high_use, prob = 0)
## [1] 0.2984293
cv <- cv.glm(data = alc, cost = loss_func, glmfit = m, K = 10)
cv$delta[1]
## [1] 0.3141361
As one could expect, increasing the amount of predictors decreases the average error, assuming the predictions from the smaller model are maintained. Choosing a few optimal predictors should yield a smaller number than choosing a large number of not-so-good predictors. None of the models I created produced a smaller average error than the one on datacamp, and I would guess it to be quite difficult to find such a model. What surprised me was the amount by which the average prediction error changes between the models produced. I expected it to variate more.
summary(cars)
## speed dist
## Min. : 4.0 Min. : 2.00
## 1st Qu.:12.0 1st Qu.: 26.00
## Median :15.0 Median : 36.00
## Mean :15.4 Mean : 42.98
## 3rd Qu.:19.0 3rd Qu.: 56.00
## Max. :25.0 Max. :120.00
First we load the “Boston” data from MASS package and explore it.
library(MASS)
##
## Attaching package: 'MASS'
## The following object is masked from 'package:dplyr':
##
## select
data("Boston")
str(Boston)
## 'data.frame': 506 obs. of 14 variables:
## $ crim : num 0.00632 0.02731 0.02729 0.03237 0.06905 ...
## $ zn : num 18 0 0 0 0 0 12.5 12.5 12.5 12.5 ...
## $ indus : num 2.31 7.07 7.07 2.18 2.18 2.18 7.87 7.87 7.87 7.87 ...
## $ chas : int 0 0 0 0 0 0 0 0 0 0 ...
## $ nox : num 0.538 0.469 0.469 0.458 0.458 0.458 0.524 0.524 0.524 0.524 ...
## $ rm : num 6.58 6.42 7.18 7 7.15 ...
## $ age : num 65.2 78.9 61.1 45.8 54.2 58.7 66.6 96.1 100 85.9 ...
## $ dis : num 4.09 4.97 4.97 6.06 6.06 ...
## $ rad : int 1 2 2 3 3 3 5 5 5 5 ...
## $ tax : num 296 242 242 222 222 222 311 311 311 311 ...
## $ ptratio: num 15.3 17.8 17.8 18.7 18.7 18.7 15.2 15.2 15.2 15.2 ...
## $ black : num 397 397 393 395 397 ...
## $ lstat : num 4.98 9.14 4.03 2.94 5.33 ...
## $ medv : num 24 21.6 34.7 33.4 36.2 28.7 22.9 27.1 16.5 18.9 ...
summary(Boston)
## crim zn indus chas
## Min. : 0.00632 Min. : 0.00 Min. : 0.46 Min. :0.00000
## 1st Qu.: 0.08204 1st Qu.: 0.00 1st Qu.: 5.19 1st Qu.:0.00000
## Median : 0.25651 Median : 0.00 Median : 9.69 Median :0.00000
## Mean : 3.61352 Mean : 11.36 Mean :11.14 Mean :0.06917
## 3rd Qu.: 3.67708 3rd Qu.: 12.50 3rd Qu.:18.10 3rd Qu.:0.00000
## Max. :88.97620 Max. :100.00 Max. :27.74 Max. :1.00000
## nox rm age dis
## Min. :0.3850 Min. :3.561 Min. : 2.90 Min. : 1.130
## 1st Qu.:0.4490 1st Qu.:5.886 1st Qu.: 45.02 1st Qu.: 2.100
## Median :0.5380 Median :6.208 Median : 77.50 Median : 3.207
## Mean :0.5547 Mean :6.285 Mean : 68.57 Mean : 3.795
## 3rd Qu.:0.6240 3rd Qu.:6.623 3rd Qu.: 94.08 3rd Qu.: 5.188
## Max. :0.8710 Max. :8.780 Max. :100.00 Max. :12.127
## rad tax ptratio black
## Min. : 1.000 Min. :187.0 Min. :12.60 Min. : 0.32
## 1st Qu.: 4.000 1st Qu.:279.0 1st Qu.:17.40 1st Qu.:375.38
## Median : 5.000 Median :330.0 Median :19.05 Median :391.44
## Mean : 9.549 Mean :408.2 Mean :18.46 Mean :356.67
## 3rd Qu.:24.000 3rd Qu.:666.0 3rd Qu.:20.20 3rd Qu.:396.23
## Max. :24.000 Max. :711.0 Max. :22.00 Max. :396.90
## lstat medv
## Min. : 1.73 Min. : 5.00
## 1st Qu.: 6.95 1st Qu.:17.02
## Median :11.36 Median :21.20
## Mean :12.65 Mean :22.53
## 3rd Qu.:16.95 3rd Qu.:25.00
## Max. :37.97 Max. :50.00
names(Boston)
## [1] "crim" "zn" "indus" "chas" "nox" "rm" "age"
## [8] "dis" "rad" "tax" "ptratio" "black" "lstat" "medv"
The “Boston”-data is comprised of 506 observations of 14 different variables. The “Names()”-function provides the names of the variables included. The function “Summary()” produces the distributions of each variable.
Now we explore the relationship between variables.
library(corrplot)
## corrplot 0.84 loaded
library(tidyverse)
## ── Attaching packages ───────────────────────────────────────────────────────────────────────── tidyverse 1.2.1 ──
## ✔ tibble 1.4.2 ✔ purrr 0.2.5
## ✔ readr 1.2.1 ✔ stringr 1.3.1
## ✔ tibble 1.4.2 ✔ forcats 0.3.0
## ── Conflicts ──────────────────────────────────────────────────────────────────────────── tidyverse_conflicts() ──
## ✖ dplyr::filter() masks stats::filter()
## ✖ dplyr::lag() masks stats::lag()
## ✖ MASS::select() masks dplyr::select()
cor_matrix<-cor(Boston) %>% round(digits=2)
corrplot(cor_matrix, type="upper", cl.pos = "b",tl.pos = "d",tl.cex = 0.6 )
In the graph, the blue colour represents positive correlation between variables while the red rpresents the negatives. The darker the colour and the bigger the ball, the stronger the correlation is. For example, the big blue ball between “rad” and “tax” tells that there is a strong correlation between access to highways and property tax rate.
Now we’ll standardise the data
boston_scaled <- scale(Boston)
summary(boston_scaled)
## crim zn indus
## Min. :-0.419367 Min. :-0.48724 Min. :-1.5563
## 1st Qu.:-0.410563 1st Qu.:-0.48724 1st Qu.:-0.8668
## Median :-0.390280 Median :-0.48724 Median :-0.2109
## Mean : 0.000000 Mean : 0.00000 Mean : 0.0000
## 3rd Qu.: 0.007389 3rd Qu.: 0.04872 3rd Qu.: 1.0150
## Max. : 9.924110 Max. : 3.80047 Max. : 2.4202
## chas nox rm age
## Min. :-0.2723 Min. :-1.4644 Min. :-3.8764 Min. :-2.3331
## 1st Qu.:-0.2723 1st Qu.:-0.9121 1st Qu.:-0.5681 1st Qu.:-0.8366
## Median :-0.2723 Median :-0.1441 Median :-0.1084 Median : 0.3171
## Mean : 0.0000 Mean : 0.0000 Mean : 0.0000 Mean : 0.0000
## 3rd Qu.:-0.2723 3rd Qu.: 0.5981 3rd Qu.: 0.4823 3rd Qu.: 0.9059
## Max. : 3.6648 Max. : 2.7296 Max. : 3.5515 Max. : 1.1164
## dis rad tax ptratio
## Min. :-1.2658 Min. :-0.9819 Min. :-1.3127 Min. :-2.7047
## 1st Qu.:-0.8049 1st Qu.:-0.6373 1st Qu.:-0.7668 1st Qu.:-0.4876
## Median :-0.2790 Median :-0.5225 Median :-0.4642 Median : 0.2746
## Mean : 0.0000 Mean : 0.0000 Mean : 0.0000 Mean : 0.0000
## 3rd Qu.: 0.6617 3rd Qu.: 1.6596 3rd Qu.: 1.5294 3rd Qu.: 0.8058
## Max. : 3.9566 Max. : 1.6596 Max. : 1.7964 Max. : 1.6372
## black lstat medv
## Min. :-3.9033 Min. :-1.5296 Min. :-1.9063
## 1st Qu.: 0.2049 1st Qu.:-0.7986 1st Qu.:-0.5989
## Median : 0.3808 Median :-0.1811 Median :-0.1449
## Mean : 0.0000 Mean : 0.0000 Mean : 0.0000
## 3rd Qu.: 0.4332 3rd Qu.: 0.6024 3rd Qu.: 0.2683
## Max. : 0.4406 Max. : 3.5453 Max. : 2.9865
Now all the observations are using the same scale. Making assumptions about the summary for example is meaningful.
Then we must turn “boston_scaled” back into a data.frame
boston_scaled <- as.data.frame(boston_scaled)
These lines give us the cathegorical variable “crime”
bins <- quantile(boston_scaled$crim)
crime <- cut(boston_scaled$crim, breaks = bins, include.lowest = TRUE, labels = c("low", "med_low", "med_high", "high"))
And these replace the old variable “crim” with the cathegorical crime
boston_scaled <- dplyr::select(boston_scaled, -crim)
boston_scaled <- data.frame(boston_scaled, crime)
Then we divide the data to train with 80% of the data and test with 20% of the data.
n <- nrow(boston_scaled)
ind <- sample(n, size = n * 0.8)
train <- boston_scaled[ind,]
test <- boston_scaled[-ind,]
lda.fit <- lda(crime ~ ., data = train)
lda.arrows <- function(x, myscale = 1, arrow_heads = 0.1, color = "red", tex = 0.75, choices = c(1,2)){
heads <- coef(x)
arrows(x0 = 0, y0 = 0,
x1 = myscale * heads[,choices[1]],
y1 = myscale * heads[,choices[2]], col=color, length = arrow_heads)
text(myscale * heads[,choices], labels = row.names(heads),
cex = tex, col=color, pos=3)
}
classes <- as.numeric(train$crime)
plot(lda.fit, dimen = 2, col=classes)
lda.arrows(lda.fit, myscale = 2)
Looking at the bi-plot, it’s clear that the “rad”-variable acts (on its own) as a predictor of “high crime rate” in the Boston data. The other 12 variables are associated with low, medium low and medium high rates of crime. The grouping based on these 12 variables is quite vague and it is difficult to see whether any of the variables can accurately/adequately sort the associated observations.
crime_cat<-test$crime
test<-dplyr::select(test, -crime)
lda.pred<-predict(lda.fit, newdata = test)
table(correct = crime_cat, predicted = lda.pred$class)
## predicted
## correct low med_low med_high high
## low 14 11 4 0
## med_low 6 19 2 0
## med_high 0 3 14 0
## high 0 0 0 29
The amount of correct cases and of predicted cases for each of the cathegories (low, med_low, med_high, high) varies between every sample matrix. The change is to be expected as the sets we have created have been randomly classified. There is much less variation between predictions for the “high” class than there is in the predictions of the others.
data(Boston)
boston_scaled1<-as.data.frame(scale(Boston))
dist_eu<-dist(boston_scaled1)
summary(dist_eu)
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## 0.1343 3.4625 4.8241 4.9111 6.1863 14.3970
head(boston_scaled1)
## crim zn indus chas nox rm
## 1 -0.4193669 0.2845483 -1.2866362 -0.2723291 -0.1440749 0.4132629
## 2 -0.4169267 -0.4872402 -0.5927944 -0.2723291 -0.7395304 0.1940824
## 3 -0.4169290 -0.4872402 -0.5927944 -0.2723291 -0.7395304 1.2814456
## 4 -0.4163384 -0.4872402 -1.3055857 -0.2723291 -0.8344581 1.0152978
## 5 -0.4120741 -0.4872402 -1.3055857 -0.2723291 -0.8344581 1.2273620
## 6 -0.4166314 -0.4872402 -1.3055857 -0.2723291 -0.8344581 0.2068916
## age dis rad tax ptratio black
## 1 -0.1198948 0.140075 -0.9818712 -0.6659492 -1.4575580 0.4406159
## 2 0.3668034 0.556609 -0.8670245 -0.9863534 -0.3027945 0.4406159
## 3 -0.2655490 0.556609 -0.8670245 -0.9863534 -0.3027945 0.3960351
## 4 -0.8090878 1.076671 -0.7521778 -1.1050216 0.1129203 0.4157514
## 5 -0.5106743 1.076671 -0.7521778 -1.1050216 0.1129203 0.4406159
## 6 -0.3508100 1.076671 -0.7521778 -1.1050216 0.1129203 0.4101651
## lstat medv
## 1 -1.0744990 0.1595278
## 2 -0.4919525 -0.1014239
## 3 -1.2075324 1.3229375
## 4 -1.3601708 1.1815886
## 5 -1.0254866 1.4860323
## 6 -1.0422909 0.6705582
The scaled Boston data will now be used for K-means clustering. It isn’t trivial (in many cases) to investigate on the number of clusters that can classify the data. Therefore, we need to first randomize the usage of a certain number of clusters.
First let’s start with a random number cluster. Let us choose k=4 and apply k-means on the data.
kmm = kmeans(boston_scaled1,6,nstart = 50 ,iter.max = 15)
The elbow method is one good technique using which we can estimate the number of clusters.
library(ggplot2)
set.seed(1234)
k.max <- 15
data <- boston_scaled1
wss <- sapply(1:k.max,
function(k){kmeans(data, k)$tot.withinss})
qplot(1:k.max, wss, geom = c("point", "line"), span = 0.2,
xlab="Number of clusters K",
ylab="Total within-clusters sum of squares")
## Warning: Ignoring unknown parameters: span
## Warning: Ignoring unknown parameters: span
The elbow plot seems to indicate that we may not find more than two clear clusters but it’s good to confirm predictions using another method because there is no shortage of methods for analyses like these. Let’s try the “NbClust”- package.
library(NbClust)
nb <- NbClust(boston_scaled1, diss=NULL, distance = "euclidean",
min.nc=2, max.nc=5, method = "kmeans",
index = "all", alphaBeale = 0.1)
## *** : The Hubert index is a graphical method of determining the number of clusters.
## In the plot of Hubert index, we seek a significant knee that corresponds to a
## significant increase of the value of the measure i.e the significant peak in Hubert
## index second differences plot.
##
## *** : The D index is a graphical method of determining the number of clusters.
## In the plot of D index, we seek a significant knee (the significant peak in Dindex
## second differences plot) that corresponds to a significant increase of the value of
## the measure.
##
## *******************************************************************
## * Among all indices:
## * 12 proposed 2 as the best number of clusters
## * 6 proposed 3 as the best number of clusters
## * 3 proposed 4 as the best number of clusters
## * 3 proposed 5 as the best number of clusters
##
## ***** Conclusion *****
##
## * According to the majority rule, the best number of clusters is 2
##
##
## *******************************************************************
hist(nb$Best.nc[1,], breaks = max(na.omit(nb$Best.nc[1,])))
Now, it’s easier to see that the data is described better with two clusters. With that, we should run the k-means algorithm again.
km_final = kmeans(boston_scaled1, centers = 2)
pairs(boston_scaled1[3:9], col=km_final$cluster)
The clusters in the above plot are divided into two groups and outlined using the colors red and black. Some of the pairs are better grouped than other ones in the plot. One of the important observations can be made with the “chas”-variable where the observations in all of the pairs formed by it are wrongly clustered. Still, clusters formed by the “rad” variable are better separated.
Bonus:
Now, we will use a randomly selected cluster number (k=6) and perform LDA. We shall follow the the basic steps of scaling and distance calculation. Afterwards, we will find out how the biplot looks (of the whole data set) as we try to group it into six different categories.
boston_scaled2<-as.data.frame(scale(Boston))
head(boston_scaled2)
## crim zn indus chas nox rm
## 1 -0.4193669 0.2845483 -1.2866362 -0.2723291 -0.1440749 0.4132629
## 2 -0.4169267 -0.4872402 -0.5927944 -0.2723291 -0.7395304 0.1940824
## 3 -0.4169290 -0.4872402 -0.5927944 -0.2723291 -0.7395304 1.2814456
## 4 -0.4163384 -0.4872402 -1.3055857 -0.2723291 -0.8344581 1.0152978
## 5 -0.4120741 -0.4872402 -1.3055857 -0.2723291 -0.8344581 1.2273620
## 6 -0.4166314 -0.4872402 -1.3055857 -0.2723291 -0.8344581 0.2068916
## age dis rad tax ptratio black
## 1 -0.1198948 0.140075 -0.9818712 -0.6659492 -1.4575580 0.4406159
## 2 0.3668034 0.556609 -0.8670245 -0.9863534 -0.3027945 0.4406159
## 3 -0.2655490 0.556609 -0.8670245 -0.9863534 -0.3027945 0.3960351
## 4 -0.8090878 1.076671 -0.7521778 -1.1050216 0.1129203 0.4157514
## 5 -0.5106743 1.076671 -0.7521778 -1.1050216 0.1129203 0.4406159
## 6 -0.3508100 1.076671 -0.7521778 -1.1050216 0.1129203 0.4101651
## lstat medv
## 1 -1.0744990 0.1595278
## 2 -0.4919525 -0.1014239
## 3 -1.2075324 1.3229375
## 4 -1.3601708 1.1815886
## 5 -1.0254866 1.4860323
## 6 -1.0422909 0.6705582
set.seed(1234)
km_bs2<-kmeans(dist_eu, centers = 6)
head(km_bs2)
## $cluster
## 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18
## 6 6 6 6 6 6 6 4 4 6 4 6 6 4 4 4 6 4
## 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36
## 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4
## 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54
## 4 6 6 1 1 6 6 6 6 6 6 4 4 6 6 6 6 6
## 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72
## 1 1 1 1 6 6 6 6 6 6 1 1 1 6 6 6 6 6
## 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90
## 6 6 6 6 4 4 4 6 6 6 6 6 6 6 6 6 6 6
## 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108
## 6 6 6 6 4 6 6 3 3 6 4 4 4 4 4 4 4 4
## 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126
## 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 2 4 4
## 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144
## 2 2 2 2 4 4 4 4 2 2 2 2 2 2 2 2 5 2
## 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162
## 5 5 5 5 5 2 2 2 5 2 5 5 5 3 4 2 3 3
## 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180
## 3 3 4 4 3 4 4 4 4 4 4 4 4 6 6 6 6 6
## 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198
## 3 6 6 6 4 6 3 6 6 1 1 1 1 1 1 1 1 1
## 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216
## 1 1 1 1 1 1 1 6 6 4 3 3 3 3 3 6 4 6
## 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234
## 3 4 3 3 3 3 3 6 3 3 3 6 3 6 4 6 3 3
## 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 251 252
## 3 4 3 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6
## 253 254 255 256 257 258 259 260 261 262 263 264 265 266 267 268 269 270
## 1 1 1 1 1 3 3 3 3 3 3 3 3 3 3 3 3 3
## 271 272 273 274 275 276 277 278 279 280 281 282 283 284 285 286 287 288
## 6 6 6 3 3 6 3 3 6 6 3 6 3 1 1 1 1 6
## 289 290 291 292 293 294 295 296 297 298 299 300 301 302 303 304 305 306
## 6 1 1 1 1 6 6 6 6 6 1 1 1 6 6 6 6 6
## 307 308 309 310 311 312 313 314 315 316 317 318 319 320 321 322 323 324
## 6 6 4 4 4 4 4 4 4 4 4 4 4 4 6 6 6 4
## 325 326 327 328 329 330 331 332 333 334 335 336 337 338 339 340 341 342
## 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 6 1
## 343 344 345 346 347 348 349 350 351 352 353 354 355 356 357 358 359 360
## 6 6 1 6 6 1 1 1 6 1 1 1 1 1 5 5 5 2
## 361 362 363 364 365 366 367 368 369 370 371 372 373 374 375 376 377 378
## 2 2 2 5 5 5 2 5 5 5 5 2 5 5 5 2 2 2
## 379 380 381 382 383 384 385 386 387 388 389 390 391 392 393 394 395 396
## 2 2 5 2 2 2 5 5 5 5 5 2 2 2 2 2 2 2
## 397 398 399 400 401 402 403 404 405 406 407 408 409 410 411 412 413 414
## 2 2 5 2 5 2 2 2 5 5 5 2 2 2 5 5 5 5
## 415 416 417 418 419 420 421 422 423 424 425 426 427 428 429 430 431 432
## 5 5 5 5 5 5 2 2 2 5 5 5 5 5 5 5 2 5
## 433 434 435 436 437 438 439 440 441 442 443 444 445 446 447 448 449 450
## 2 2 5 5 5 5 5 2 2 2 2 2 2 5 2 2 2 2
## 451 452 453 454 455 456 457 458 459 460 461 462 463 464 465 466 467 468
## 5 2 2 2 5 5 5 5 2 2 2 2 2 2 2 2 5 2
## 469 470 471 472 473 474 475 476 477 478 479 480 481 482 483 484 485 486
## 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
## 487 488 489 490 491 492 493 494 495 496 497 498 499 500 501 502 503 504
## 2 2 2 2 5 2 2 4 4 4 4 4 4 4 4 4 4 4
## 505 506
## 4 4
##
## $centers
## 1 2 3 4 5 6 7 8
## 1 3.989644 4.556297 4.216580 3.977768 4.072917 4.089124 4.248097 4.850842
## 2 5.635860 5.015922 5.810840 6.243394 6.219170 5.797678 5.007134 5.045384
## 3 4.115845 4.367908 3.914214 4.415556 4.277226 4.521520 4.462950 4.591271
## 4 3.322873 2.419949 3.555546 3.901515 3.917887 3.259432 2.872770 3.145128
## 5 7.347551 6.917018 7.668887 8.029178 8.008552 7.594726 6.746593 6.719663
## 6 2.552963 2.191615 2.547985 2.481257 2.636215 2.126035 2.463163 3.260455
## 9 10 11 12 13 14 15 16
## 1 6.023239 4.730761 5.085827 4.546510 4.256435 5.022876 5.346690 5.064489
## 2 5.275376 5.034209 5.024306 5.008656 5.191566 4.483294 4.239085 4.500312
## 3 5.861940 4.897185 5.053174 4.724166 4.806196 5.041859 5.037049 5.123212
## 4 3.802664 3.078288 3.240106 2.958259 3.171899 2.294340 2.083575 2.330854
## 5 6.637733 6.672022 6.656885 6.725987 6.831291 6.522547 6.271019 6.514117
## 6 4.420281 3.050288 3.460627 2.800817 2.548810 2.498158 2.847417 2.519525
## 17 18 19 20 21 22 23 24
## 1 4.839017 5.494447 5.410418 5.409972 6.301722 5.559564 5.849309 6.119225
## 2 4.932293 4.118743 4.699219 4.231080 4.140866 4.107180 4.064205 4.123917
## 3 5.188031 5.159236 5.556072 5.185846 5.777782 5.080391 5.333884 5.590056
## 4 2.926372 2.006490 2.829410 2.073005 2.478201 1.996680 2.200197 2.363123
## 5 6.848068 6.136584 6.246617 6.243108 5.944153 6.154788 6.070741 6.047729
## 6 2.477710 2.972866 3.035484 2.815474 3.883785 3.047242 3.413583 3.706860
## 25 26 27 28 29 30 31 32
## 1 5.776453 5.909337 5.645826 5.792679 5.463721 5.291108 6.251560 5.790675
## 2 4.125236 4.229138 4.173627 4.154204 4.209655 4.253839 4.190000 4.132815
## 3 5.355804 5.648491 5.331440 5.423799 4.956368 4.757484 5.818922 5.290357
## 4 2.152358 2.399737 2.130704 2.313981 2.194705 2.226566 2.563711 2.185395
## 5 6.124494 5.850285 6.119300 5.848617 6.281408 6.323214 5.926407 6.111869
## 6 3.317906 3.492059 3.174430 3.407128 3.072595 2.917289 3.883866 3.341829
## 33 34 35 36 37 38 39 40
## 1 6.577978 6.113220 6.286376 5.003424 4.975828 4.672432 4.567581 2.437628
## 2 4.543962 4.083659 4.244460 4.504907 4.504214 4.851253 4.995628 6.988766
## 3 6.168152 5.623677 5.717537 4.728770 4.767845 4.847078 4.787796 5.456166
## 4 3.295133 2.297075 2.760000 2.036929 2.052171 2.484306 2.720323 5.019539
## 5 5.702765 5.899302 5.635547 6.472198 6.389736 6.751702 6.860251 8.586641
## 6 4.437132 3.655982 4.014459 2.356225 2.324457 2.085109 2.100542 3.469146
## 41 42 43 44 45 46 47 48
## 1 2.550075 4.003727 4.101822 4.105741 4.205545 4.493890 4.535762 5.127133
## 2 7.347068 6.266063 6.066725 6.010008 5.405380 5.401641 5.323536 4.969192
## 3 5.469978 4.947438 5.088076 5.079073 4.810066 5.080046 5.057556 5.071546
## 4 5.447668 4.089165 3.798403 3.739937 2.899376 2.938610 2.889613 2.590240
## 5 8.944151 7.985202 7.757987 7.727039 7.185569 7.146905 7.056687 6.715830
## 6 3.806323 2.464106 2.277093 2.245886 1.890630 2.124631 2.187826 2.870058
## 49 50 51 52 53 54 55 56
## 1 6.354068 4.788056 3.687296 3.635669 3.127248 3.365371 3.768251 2.573205
## 2 5.425549 5.185207 5.660587 5.607665 6.251113 6.093472 6.228695 8.172561
## 3 6.206363 5.152123 5.037840 4.798345 4.875844 5.098446 6.488456 6.248718
## 4 3.649819 2.729138 3.311553 3.194530 3.999725 3.806354 4.738612 6.360064
## 5 6.857506 6.903606 7.327416 7.333311 7.954340 7.750576 7.846534 9.656599
## 6 4.374890 2.484987 2.216591 2.155992 2.202966 2.192392 4.011314 4.620562
## 57 58 59 60 61 62 63 64
## 1 2.435993 2.586150 3.455264 3.762957 4.163099 4.634886 3.692547 3.384146
## 2 7.625711 8.169946 5.852530 5.357849 5.193164 4.988228 5.388941 5.749506
## 3 6.314081 6.255593 5.396948 5.291164 5.423722 5.411219 4.967901 5.080093
## 4 5.728217 6.380166 3.850185 3.257986 3.128914 3.007457 3.306577 3.782189
## 5 9.093653 9.562610 7.619436 7.182935 6.981514 6.757826 7.282673 7.580278
## 6 4.138053 4.788808 2.369128 2.238707 2.577586 3.001430 2.348247 2.423646
## 65 66 67 68 69 70 71 72
## 1 3.572872 2.365488 2.854471 3.828722 4.245479 3.861492 4.311560 4.482338
## 2 6.803815 7.202476 6.871459 5.702754 5.382884 5.506994 5.679697 5.332385
## 3 5.070095 5.920134 6.075955 5.331567 5.513971 5.232351 5.172823 5.258275
## 4 4.571372 5.363377 5.039822 3.540862 3.214330 3.286807 3.670384 3.233668
## 5 8.474576 8.706790 8.325184 7.481800 7.133931 7.317062 7.509722 7.139492
## 6 3.099810 3.755717 3.762213 2.164752 2.377335 2.067120 2.395258 2.279879
## 73 74 75 76 77 78 79 80
## 1 4.423047 4.374894 4.565665 4.571969 4.993178 4.715682 4.645174 4.703818
## 2 5.670343 5.628241 5.253844 4.504533 4.080734 4.392771 4.369389 4.613917
## 3 5.331200 5.256931 5.138078 4.739219 4.676271 4.796607 4.781211 5.037161
## 4 3.633211 3.612120 3.532216 2.554765 2.115305 2.435091 2.406743 2.698489
## 5 7.496987 7.426016 7.172186 6.550720 6.164051 6.445026 6.421550 6.621032
## 6 2.419650 2.395619 2.582255 2.208724 2.569263 2.284706 2.281898 2.322846
## 81 82 83 84 85 86 87 88
## 1 3.228722 3.647245 3.352955 3.510806 4.214393 4.216222 4.470996 4.539526
## 2 5.833680 5.345002 5.671433 5.439196 5.298921 5.378578 5.181960 5.119600
## 3 4.611003 4.507704 4.824876 4.799211 4.493640 4.250144 4.736784 4.543074
## 4 3.593223 2.978716 3.362220 3.049922 2.723815 2.845202 2.603436 2.477017
## 5 7.679009 7.247432 7.495607 7.269305 7.155841 7.257393 6.986917 6.981295
## 6 2.077143 2.128207 1.941076 1.906614 1.839655 1.960338 2.004413 2.011357
## 89 90 91 92 93 94 95 96
## 1 4.787782 4.431266 4.656816 4.754404 4.105175 4.001644 4.521147 4.347592
## 2 5.260876 5.460377 5.023131 4.997348 4.772459 5.169144 4.479851 5.437460
## 3 4.086432 3.906040 4.252949 4.267811 4.510455 4.766874 4.611235 4.143402
## 4 2.894806 3.107514 2.443156 2.419531 2.751041 3.222217 2.448424 2.937590
## 5 7.155386 7.332941 6.878036 6.862533 6.774331 7.083584 6.505216 7.188899
## 6 2.659893 2.401307 2.216247 2.322228 2.415933 2.468939 2.704529 2.182013
## 97 98 99 100 101 102 103 104
## 1 4.715695 4.926015 4.640776 4.444450 5.282563 5.152315 6.572203 5.683531
## 2 5.051112 6.412041 6.764467 5.837829 4.205067 4.305317 5.036975 3.815398
## 3 4.508034 3.931800 4.158120 3.883013 4.489959 4.495810 6.000236 5.001289
## 4 2.400338 4.464342 4.810546 3.603211 2.414290 2.493991 3.966604 1.972705
## 5 6.868421 8.203118 8.491487 7.681807 6.393702 6.492260 5.811685 5.987192
## 6 2.261612 3.692387 3.630574 2.739459 2.966666 2.843788 4.692793 3.172095
## 105 106 107 108 109 110 111 112
## 1 5.724543 6.103378 6.104999 5.770964 5.777602 5.809233 5.260548 5.174233
## 2 3.840428 3.789013 3.785737 3.801714 3.887880 3.778476 4.058712 3.895295
## 3 4.956142 5.253274 5.307506 4.990050 4.894350 5.027813 4.918935 4.183520
## 4 2.022137 2.164155 2.196416 2.023648 2.172750 2.042266 2.184470 2.238546
## 5 6.014221 5.881611 5.856170 5.944714 6.084653 5.930743 6.185964 6.069764
## 6 3.223448 3.618628 3.631351 3.259679 3.351457 3.335422 2.743048 2.868558
## 113 114 115 116 117 118 119 120
## 1 5.795991 5.778504 5.457332 5.719642 5.202323 5.373780 5.497713 5.357061
## 2 3.601847 3.596459 3.722199 3.590667 3.748787 3.744213 3.671311 3.776235
## 3 4.819193 4.774286 4.530960 4.818453 4.451377 4.589012 4.741708 4.798190
## 4 2.075218 2.106269 2.052459 2.053031 1.971584 1.988655 2.048517 2.045794
## 5 5.667421 5.680606 5.851170 5.493919 5.878062 5.869090 5.544023 5.809181
## 6 3.375466 3.392521 3.026294 3.301736 2.747953 2.915253 3.063432 2.869590
## 121 122 123 124 125 126 127 128
## 1 6.426088 6.565457 6.806695 7.305465 6.897705 6.650747 7.533959 7.099802
## 2 4.261019 4.162980 4.128457 4.247333 4.123875 4.163650 4.355189 3.161437
## 3 5.427653 5.424854 5.565025 6.069215 5.659762 5.427403 6.344535 5.999576
## 4 2.985164 2.938368 3.039074 3.475730 3.062302 2.973639 3.677551 2.962007
## 5 6.237519 6.139760 6.064278 6.001360 6.051491 6.152869 5.974765 5.445330
## 6 4.116775 4.252645 4.510005 5.058229 4.583383 4.343081 5.287399 4.735059
## 129 130 131 132 133 134 135 136
## 1 6.875876 7.154803 6.726119 6.686918 6.596530 6.821369 7.166802 6.870993
## 2 3.183589 3.174651 3.265601 3.234532 3.348169 3.162883 3.338913 3.134950
## 3 5.627423 6.120486 5.509731 5.516882 5.382470 5.779404 6.139554 5.674601
## 4 2.931268 3.021401 2.885217 2.835481 2.871725 2.806058 3.188140 2.903821
## 5 5.604137 5.425648 5.688097 5.652880 5.721190 5.497188 5.035538 5.535608
## 6 4.590233 4.791289 4.456575 4.402201 4.350142 4.479053 4.894039 4.582035
## 137 138 139 140 141 142 143 144
## 1 6.929533 6.859261 7.327005 7.036231 7.324311 8.387851 9.118028 8.148386
## 2 3.098547 3.195797 3.203702 3.121999 3.270140 4.203114 6.057048 4.491078
## 3 5.819167 5.632765 6.197877 5.809014 6.167568 7.327389 6.736697 6.601594
## 4 2.859060 2.928458 3.172007 2.969872 3.289011 4.421385 6.210476 4.719098
## 5 5.406565 5.610438 5.411571 5.483828 5.434774 5.732297 6.519423 5.705948
## 6 4.585322 4.572210 4.994596 4.721431 5.047669 6.196553 7.427033 6.200054
## 145 146 147 148 149 150 151 152
## 1 8.591160 8.420611 8.051529 8.485530 8.220414 7.812856 7.329573 7.603008
## 2 4.881773 4.956580 4.786268 4.850486 4.658853 4.298230 4.279168 4.390872
## 3 7.209721 6.881696 6.562636 7.091389 6.756783 6.281936 5.599987 6.029305
## 4 5.120965 5.221320 4.864032 5.058645 4.839584 4.425501 4.201583 4.325365
## 5 5.882920 5.395652 5.350043 5.860027 5.668932 5.539694 5.844264 5.733672
## 6 6.628290 6.634143 6.205886 6.539074 6.293195 5.851136 5.439102 5.651936
## 153 154 155 156 157 158 159 160
## 1 8.622664 7.648725 8.381752 8.889137 8.425203 6.168678 6.265700 7.165808
## 2 6.067192 4.403229 5.843835 6.536516 5.328492 5.218020 4.320602 4.558378
## 3 6.369979 6.052779 5.844207 6.703763 7.158351 4.234387 4.756091 5.368031
## 4 5.967163 4.417624 5.805631 6.566625 5.400744 4.276378 3.305864 4.351927
## 5 6.541819 5.446370 6.344801 6.334474 5.503366 6.942094 6.074535 6.178603
## 6 6.952748 5.752673 6.793409 7.450863 6.650053 4.652464 4.273222 5.383270
## 161 162 163 164 165 166 167 168
## 1 7.231434 6.383671 7.606315 7.711715 6.150603 6.283786 6.542030 6.239898
## 2 5.940257 6.088162 7.394089 7.646620 4.086328 4.360674 6.228342 4.356613
## 3 4.605274 4.398804 4.791045 4.937649 4.851661 4.926498 4.456582 5.095670
## 4 5.239834 5.208814 6.712875 6.998166 3.062315 3.452702 5.427142 3.432231
## 5 6.821006 7.745103 8.432676 8.695086 5.936568 5.663492 7.854149 5.576630
## 6 5.752473 5.237762 6.745173 6.961257 4.080738 4.385762 5.475612 4.315636
## 169 170 171 172 173 174 175 176
## 1 6.213385 6.133807 6.433082 6.312035 5.454412 4.962647 4.941506 4.309193
## 2 4.170734 4.100748 4.054129 4.025673 4.699883 4.808037 4.816591 5.496225
## 3 4.728033 4.677209 5.202442 5.015219 4.676351 4.091021 4.407110 4.153032
## 4 3.234454 3.142836 3.181914 3.077576 2.488721 2.512347 2.447970 3.326034
## 5 5.730715 5.794348 5.516106 5.715890 6.426784 6.668081 6.607389 7.275149
## 6 4.254128 4.150282 4.374444 4.230784 3.104965 2.654763 2.534686 2.342553
## 177 178 179 180 181 182 183 184
## 1 4.520962 4.655885 4.649899 4.604653 5.132343 4.814462 5.087352 5.054530
## 2 5.015596 4.976181 5.157347 5.945635 6.198433 5.587189 5.931557 5.543818
## 3 4.411335 4.095254 3.737891 3.879091 3.800673 4.190561 3.860567 4.061937
## 4 2.658053 2.616342 2.975519 3.642452 4.178165 3.143454 3.744498 3.144853
## 5 6.792977 6.830833 7.010189 7.720425 7.949502 7.318332 7.703218 7.337983
## 6 2.175426 2.365924 2.589714 2.810682 3.656914 2.701373 3.342620 2.979474
## 185 186 187 188 189 190 191 192
## 1 5.360158 4.777155 5.085672 3.049814 2.837691 2.892236 2.592917 2.487691
## 2 5.146074 5.258702 6.977902 6.090983 6.253786 6.421824 6.840347 6.509686
## 3 4.706625 4.276810 4.103340 4.369622 4.665779 4.360736 4.840840 4.814221
## 4 2.617485 2.667473 5.069928 4.220068 4.355866 4.608931 5.027524 4.620020
## 5 6.823279 6.988966 8.637738 7.764729 7.876360 8.097468 8.409214 8.135143
## 6 3.009695 2.461779 4.108449 2.947084 2.866184 3.171421 3.299804 2.939362
## 193 194 195 196 197 198 199 200
## 1 2.626002 2.323019 2.285881 3.495329 2.818135 2.825122 2.840680 2.451539
## 2 6.916387 7.350478 7.173909 8.592641 8.185358 7.919777 8.103044 7.965488
## 3 4.786382 5.315615 5.265629 5.625695 5.786297 5.784978 5.720384 6.255528
## 4 5.115810 5.261122 5.038340 6.858470 6.362933 6.100498 6.288002 6.311681
## 5 8.533158 8.873489 8.672208 10.009282 9.580192 9.208468 9.481059 9.444290
## 6 3.385297 3.423873 3.258558 5.286849 4.731058 4.582926 4.715512 4.639590
## 201 202 203 204 205 206 207
## 1 2.456624 2.615509 2.868195 3.538131 3.737246 4.677119 4.523642
## 2 7.969849 7.156198 8.271244 8.640337 8.822374 4.966944 4.612421
## 3 6.272606 5.771920 5.739854 5.855113 5.957838 4.945805 4.407545
## 4 6.329487 5.273529 6.554190 6.965429 7.174721 2.820461 2.266758
## 5 9.430213 8.587107 9.723775 10.042167 10.216692 6.837520 6.613955
## 6 4.653597 3.907488 4.866644 5.491799 5.693985 2.252863 1.996460
## 208 209 210 211 212 213 214 215
## 1 5.173003 6.173648 7.246427 6.672900 7.168488 6.358530 4.424781 5.994199
## 2 4.338029 5.951508 5.923358 5.785418 5.899356 5.931043 4.957469 5.447417
## 3 4.839209 4.297639 5.214301 4.486356 5.179802 4.522080 4.441468 6.128544
## 4 2.088170 4.501917 4.748828 4.456045 4.719108 4.521710 2.774437 3.942573
## 5 6.238923 7.056415 6.886396 6.882747 6.859678 7.017952 6.877368 6.804923
## 6 2.684155 4.559083 5.472929 4.942984 5.391736 4.669469 2.088834 4.075614
## 216 217 218 219 220 221 222 223
## 1 4.533967 6.461391 5.090497 6.968673 6.593520 6.320911 6.799719 6.130295
## 2 4.734048 5.887167 4.502200 5.707295 5.831456 6.068344 5.809474 6.083430
## 3 4.493721 4.333352 3.927803 4.474244 4.098632 3.855927 4.507648 3.793452
## 4 2.431159 4.642940 2.604000 4.619602 4.623502 4.781149 4.654611 4.752233
## 5 6.701716 6.923664 6.481639 6.712071 6.932306 7.216588 6.814993 7.226735
## 6 2.008161 4.833935 2.937343 5.253528 4.990749 4.858718 5.140070 4.702050
## 224 225 226 227 228 229 230 231
## 1 4.738585 5.386965 5.891695 5.165618 4.738937 4.794451 4.323631 4.757661
## 2 4.706017 6.297753 6.888318 5.848384 4.984604 6.583434 5.480585 4.442431
## 3 3.859178 3.856074 4.287951 3.761622 3.704484 4.327344 4.344291 4.345763
## 4 2.632171 4.857703 5.604564 4.291528 3.086868 5.025870 3.556647 2.180368
## 5 6.676587 8.061548 8.562013 7.691942 6.882629 8.267586 7.279603 6.313200
## 6 2.510992 4.285144 5.053107 3.807224 2.766869 3.866941 2.455648 2.274652
## 232 233 234 235 236 237 238 239
## 1 4.653852 5.135020 5.281054 5.952219 4.649091 6.018095 4.490512 2.932965
## 2 5.189298 6.314557 6.527581 6.182940 4.494536 6.049817 5.234441 6.100275
## 3 3.705792 3.899503 3.957570 3.819634 4.306913 3.896708 3.743105 4.916380
## 4 3.349510 4.826196 5.081229 4.795798 2.237307 4.663958 3.356024 4.006857
## 5 7.086045 8.097837 8.247294 7.256051 6.371138 7.184499 7.164135 7.763565
## 6 2.845373 4.094662 4.348568 4.582063 2.164414 4.571565 2.701412 2.261099
## 240 241 242 243 244 245 246 247
## 1 2.956836 3.179208 3.559831 3.174838 2.972611 4.361124 4.499702 3.449697
## 2 5.782692 5.644636 5.418724 5.676824 6.431679 5.293119 5.282827 5.730382
## 3 4.609977 4.554218 4.836874 4.812866 5.251961 5.595467 5.698876 5.306870
## 4 3.612081 3.523994 3.199172 3.505714 4.402069 3.307803 3.374542 3.724642
## 5 7.513168 7.401734 7.139957 7.340494 8.034419 6.985702 6.964082 7.498675
## 6 2.096391 2.294939 2.317889 2.233775 2.546385 2.843542 3.010876 2.298688
## 248 249 250 251 252 253 254 255
## 1 3.980918 3.426770 3.241080 3.321813 3.366958 3.347543 4.117622 2.565061
## 2 5.332551 5.535635 6.098106 6.038428 6.187201 6.732703 7.679236 7.519106
## 3 5.197006 5.027748 5.230422 5.313640 5.406880 5.560045 5.671848 6.347835
## 4 3.315715 3.504649 4.188133 4.105072 4.276291 4.932310 6.124355 5.596288
## 5 7.123772 7.327359 7.884487 7.824608 7.913195 8.440374 9.349847 8.962012
## 6 2.612063 2.227342 2.472500 2.394111 2.529107 3.107181 4.463447 4.036629
## 256 257 258 259 260 261 262 263
## 1 2.791995 2.848603 6.222798 5.518648 5.417650 5.174118 5.463188 5.971533
## 2 7.592589 8.192506 7.613422 6.131531 5.811603 5.956088 6.518475 7.320962
## 3 6.580192 5.707147 4.551395 3.894518 4.041152 3.826233 3.886648 4.317743
## 4 5.699971 6.403033 6.371304 4.637079 4.211517 4.374564 5.047654 6.017951
## 5 8.992176 9.653615 9.041679 7.629278 7.342798 7.487956 8.005527 8.762238
## 6 4.155292 4.824381 5.880265 4.531389 4.220084 4.147002 4.710711 5.556397
## 264 265 266 267 268 269 270 271
## 1 5.408871 5.364474 5.369503 5.311210 5.468341 4.684862 5.853082 4.111760
## 2 5.873985 6.084410 5.582297 5.691716 7.365150 6.850545 6.292985 5.143047
## 3 3.944671 3.834643 4.846831 4.038079 4.202225 3.938496 4.496815 4.877938
## 4 4.361095 4.543509 3.870860 4.139572 5.912661 5.158425 4.630825 2.685788
## 5 7.399951 7.595295 6.985984 7.167083 8.815364 8.370001 7.374525 6.914144
## 6 4.321892 4.369594 3.895689 4.141040 5.180260 4.218897 4.554789 2.091791
## 272 273 274 275 276 277 278 279
## 1 3.725629 3.921894 5.523364 4.973350 3.058289 4.960332 4.861229 3.070627
## 2 5.736385 5.155769 7.186009 7.238343 6.006291 7.213299 7.355393 5.795132
## 3 4.839362 4.286203 4.148237 4.380952 4.296659 4.210140 4.469765 4.503523
## 4 3.441028 2.665134 5.602045 5.598971 3.877658 5.612713 5.710319 3.612360
## 5 7.520064 7.064234 8.378912 8.386111 7.804129 8.364865 8.493915 7.564951
## 6 2.111547 1.993339 4.916068 4.705346 2.513014 4.779926 4.711343 2.285977
## 280 281 282 283 284 285 286 287
## 1 3.561388 4.216680 3.374750 5.571630 5.408034 2.345212 2.477254 2.927409
## 2 6.491419 7.105591 6.595419 8.219563 9.973467 7.928601 6.930874 7.445534
## 3 4.173615 3.975881 4.184062 4.440886 6.268257 5.936035 5.428512 6.501695
## 4 4.285849 5.167816 4.389736 6.563865 8.344298 6.072569 4.772330 5.471836
## 5 8.122015 8.703650 8.222715 9.258337 10.933893 9.363760 8.450626 8.767961
## 6 2.790991 3.947935 2.795306 5.515391 6.980733 4.422708 3.123714 4.079753
## 288 289 290 291 292 293 294 295
## 1 2.509960 2.585977 2.400932 2.683501 2.813661 2.686863 4.345410 4.479945
## 2 6.413629 6.249971 6.494620 6.930359 7.229010 6.875832 5.592884 5.181463
## 3 5.343188 5.207865 5.287981 5.569837 5.473392 5.650164 4.941731 4.796956
## 4 4.396113 4.214046 4.535171 5.074359 5.432490 5.006978 3.576391 3.058148
## 5 8.041222 7.905277 8.061694 8.582296 8.865102 8.509272 7.358111 6.995131
## 6 2.756566 2.716768 2.843575 3.668080 3.989047 3.608840 2.497209 2.387338
## 296 297 298 299 300 301 302 303
## 1 4.101880 4.215355 4.808009 2.456182 2.336450 2.394242 3.068423 2.941845
## 2 5.702683 5.379947 5.078750 7.315906 7.652372 7.121431 5.575441 5.929574
## 3 4.531097 4.405035 5.064135 5.938158 5.803548 5.507286 4.604003 4.762883
## 4 3.690081 3.281272 3.028002 5.478237 5.872746 5.284133 3.549854 3.969692
## 5 7.527753 7.235927 6.829083 8.722048 9.087048 8.634313 7.337638 7.605560
## 6 2.491650 2.393691 2.750925 3.788908 4.039227 3.734424 2.232083 2.376030
## 304 305 306 307 308 309 310 311
## 1 2.855273 3.436586 3.684046 3.978741 3.854584 4.998677 5.185967 5.719675
## 2 6.336183 6.106407 5.435975 5.842022 5.453779 4.466812 4.127252 4.624290
## 3 4.561650 4.196815 4.266337 4.017975 4.168573 4.202224 4.535816 5.594347
## 4 4.456508 4.073418 3.192729 3.845712 3.261918 2.344549 1.843049 2.847242
## 5 8.039455 7.868780 7.241481 7.658684 7.290961 6.546441 6.168368 6.187983
## 6 2.734380 2.774880 2.361712 3.039054 2.564437 2.631756 2.582365 3.293284
## 312 313 314 315 316 317 318 319
## 1 4.937184 5.460141 5.098426 5.028976 5.293601 5.460000 5.215271 4.838880
## 2 4.467670 4.023815 4.217072 4.259199 4.159874 4.029901 4.115912 4.245101
## 3 4.476328 4.594927 4.348331 4.178642 4.891978 4.889172 4.794276 4.262780
## 4 2.297145 1.850451 1.966400 2.079641 1.938234 1.959365 1.906122 1.969043
## 5 6.476538 6.069256 6.284457 6.344720 6.136907 5.966724 6.078177 6.307673
## 6 2.402724 2.904430 2.574041 2.606905 2.711944 2.970980 2.658070 2.293294
## 320 321 322 323 324 325 326 327
## 1 4.842685 4.449705 4.484974 4.585730 5.057642 4.334264 4.248227 4.277525
## 2 4.240360 4.799353 4.776401 4.757420 4.457601 5.018766 5.526219 5.218292
## 3 4.534455 4.506705 4.537503 4.811214 4.996492 4.590902 4.987239 4.873621
## 4 1.963279 2.473559 2.434921 2.406058 2.072533 2.775066 3.465771 3.042737
## 5 6.250142 6.816256 6.795014 6.731231 6.397846 6.994614 7.395759 7.139104
## 6 2.254385 1.961575 1.975895 2.005309 2.474246 1.958008 2.220200 2.005009
## 328 329 330 331 332 333 334 335
## 1 4.511237 4.336792 4.068778 4.134704 3.513382 3.127529 4.341878 4.382338
## 2 4.796609 5.372181 5.613018 5.389720 5.942590 6.090114 5.485716 5.424178
## 3 4.877258 5.105806 4.900165 4.957900 5.488342 5.279997 5.053555 5.093833
## 4 2.517471 3.305539 3.594198 3.303857 3.752625 3.884973 3.226203 3.160665
## 5 6.725423 7.068932 7.323299 7.087469 7.538669 7.661878 7.331467 7.267954
## 6 2.035908 2.350131 2.312741 2.230762 2.580536 2.403384 2.205917 2.203234
## 336 337 338 339 340 341 342 343
## 1 4.485929 4.729718 4.812037 4.629130 4.744764 4.837628 2.808348 4.362098
## 2 5.347455 5.032342 4.935566 5.124323 4.979263 4.865181 6.823411 5.448631
## 3 5.156767 5.112746 5.110110 5.016265 5.044939 4.987777 4.514441 4.784059
## 4 3.056405 2.647838 2.524309 2.778949 2.590159 2.417256 4.633530 3.331511
## 5 7.189428 6.898354 6.809633 7.000683 6.865025 6.777057 8.446366 7.165257
## 6 2.186727 2.223765 2.322145 2.157595 2.205404 2.271625 3.007511 2.617582
## 344 345 346 347 348 349 350 351
## 1 2.778316 2.366030 4.320697 4.466973 2.400876 2.213242 2.925825 3.077473
## 2 5.684615 6.353501 5.565696 5.487424 7.183736 7.319965 6.755452 6.526367
## 3 4.757585 4.927327 5.421207 5.492314 6.193135 5.934386 5.524385 5.618626
## 4 3.802233 4.548197 3.369890 3.310384 5.476084 5.437402 4.699873 4.404974
## 5 7.461637 8.044999 7.305607 7.150579 8.715944 8.820537 8.437225 8.219455
## 6 2.672462 2.940953 2.423474 2.543259 3.956148 3.799867 3.066109 2.914978
## 352 353 354 355 356 357 358 359
## 1 2.847020 3.254646 3.220675 4.018615 3.810904 8.663013 8.315674 8.225028
## 2 7.254755 7.319860 8.653858 7.691074 7.769223 4.621450 4.715344 4.749805
## 3 6.269580 6.763444 7.013329 7.521812 7.391746 6.500890 6.156007 6.172788
## 4 5.498901 5.585389 6.831393 6.079486 6.140023 5.907878 5.797393 5.786448
## 5 8.766898 8.789968 10.015464 9.117773 9.216143 5.456756 5.735313 5.758167
## 6 3.882617 4.035485 5.152518 4.846552 4.789845 6.995105 6.715094 6.630405
## 360 361 362 363 364 365 366 367
## 1 7.278021 7.215827 7.464845 7.699553 8.598542 8.542707 8.530898 7.799054
## 2 2.467536 2.805217 2.333627 2.769367 4.652258 6.207836 4.624219 2.863464
## 3 6.182375 6.025704 6.270247 6.585418 6.526351 6.398780 7.725367 6.760694
## 4 4.207340 4.344110 4.232657 4.378729 5.817697 6.961379 5.534146 4.394301
## 5 4.964540 5.192113 4.710339 4.977082 5.468166 7.258598 5.920246 4.657637
## 6 5.340790 5.361453 5.509807 5.682415 6.883975 7.392644 6.618984 5.752759
## 368 369 370 371 372 373 374 375
## 1 8.916963 7.876027 8.330037 8.374001 7.563523 8.532946 8.984585 9.736883
## 2 4.770107 4.939445 6.154059 6.280595 4.367286 5.917457 3.722610 4.767839
## 3 8.102215 6.662121 5.980344 5.981912 6.056314 6.266885 7.931335 8.798177
## 4 5.856186 5.544439 6.673537 6.801323 5.253873 6.587324 5.414656 6.304659
## 5 5.030692 6.544359 7.110024 7.285275 6.133890 6.680971 4.907474 5.412285
## 6 7.067897 6.260581 7.113702 7.203297 5.999323 7.191112 6.985946 7.809059
## 376 377 378 379 380 381 382 383
## 1 7.795568 7.924073 7.787937 8.275536 8.137870 12.821812 7.966471 8.185980
## 2 3.171317 2.549903 2.441746 3.030744 2.612679 9.894275 2.535543 2.500835
## 3 6.521129 6.722821 6.526672 7.136095 7.001182 12.116793 6.800516 7.087802
## 4 4.944969 4.652842 4.462833 5.083590 4.746519 11.163729 4.647065 4.555749
## 5 5.207964 4.521828 4.798660 4.679079 4.555128 9.663159 4.661952 4.529605
## 6 6.017927 6.001561 5.834679 6.394230 6.161471 11.755809 6.015300 6.112881
## 384 385 386 387 388 389 390 391
## 1 8.197628 9.349727 8.910330 9.193301 9.152365 8.907678 8.068366 7.677835
## 2 2.535837 4.207220 3.430304 3.965891 3.922688 3.476912 2.460378 2.173913
## 3 7.080988 8.494759 7.900222 8.245243 8.254546 7.913604 7.016902 6.584068
## 4 4.556169 5.912501 5.372451 5.774218 5.768068 5.325687 4.443905 4.162427
## 5 4.555957 4.593328 4.644399 4.813092 4.798740 4.585380 4.568138 4.613924
## 6 6.125147 7.394570 6.913418 7.236737 7.210917 6.892982 5.975128 5.602574
## 392 393 394 395 396 397 398 399
## 1 7.292592 8.487710 7.524344 7.763687 7.641959 7.677186 8.002371 9.767720
## 2 2.226899 2.983346 2.121055 2.265178 2.176869 2.197872 2.365545 4.881189
## 3 6.187448 7.518315 6.415998 6.699030 6.447121 6.503431 6.938797 8.851159
## 4 4.059557 4.886988 4.152838 4.352711 4.260815 4.238695 4.395922 6.683507
## 5 4.690817 4.584419 4.693783 4.560825 4.700448 4.730041 4.591516 5.349991
## 6 5.308181 6.426170 5.489378 5.726631 5.638596 5.653609 5.914268 7.989079
## 400 401 402 403 404 405 406 407
## 1 8.388325 8.804129 8.087911 7.825523 8.542363 9.552186 11.432606 9.054357
## 2 3.040490 3.471798 2.536220 2.216427 3.279024 4.910238 7.595875 3.994384
## 3 7.463474 7.776663 6.969235 6.627020 7.610294 8.716935 10.666205 8.166864
## 4 4.959465 5.497801 4.669753 4.375806 5.225734 6.673070 9.081383 5.594715
## 5 4.478721 4.713832 4.642624 4.544640 4.647198 5.160244 7.453981 4.877537
## 6 6.400821 6.900501 6.095533 5.820693 6.578583 7.840199 10.009989 7.043493
## 408 409 410 411 412 413 414
## 1 7.570396 7.942399 7.792350 10.375746 8.547474 9.825302 8.675535
## 2 2.751697 2.684071 3.512054 6.953620 4.401901 5.499975 4.000683
## 3 6.317911 6.868005 6.505072 9.624185 7.490223 8.978058 7.777474
## 4 4.354104 4.411296 4.984789 8.179599 5.753451 6.786214 5.592512
## 5 4.684219 4.359127 4.498617 6.248943 4.283169 4.939472 4.338544
## 6 5.605718 5.909119 6.091597 9.003486 6.898431 8.111524 6.840670
## 415 416 417 418 419 420 421
## 1 11.272810 9.378378 8.990931 9.186224 12.321200 8.708818 7.649405
## 2 6.897999 4.863694 4.682977 4.396530 8.940339 4.410853 2.275161
## 3 10.507271 8.404166 8.034930 8.321960 11.623093 7.789436 6.412841
## 4 8.419684 6.420781 6.131883 6.083046 10.281934 5.925977 4.353909
## 5 6.006137 4.335355 4.349290 4.150387 7.922425 4.248090 4.384831
## 6 9.673650 7.712449 7.339434 7.393740 11.103741 7.052418 5.696703
## 422 423 424 425 426 427 428 429
## 1 7.665560 7.356701 8.626415 8.441732 9.201143 8.265300 9.461813 8.241034
## 2 2.180745 2.508136 4.580701 4.667841 4.741929 4.569780 5.669296 3.716263
## 3 6.540748 6.403579 7.807594 7.858624 8.314551 7.743199 8.719330 7.368712
## 4 4.220529 4.151550 5.802264 5.736500 6.219861 5.681331 7.081609 5.224531
## 5 4.337641 4.332067 4.287058 4.467816 4.150667 4.462962 5.101391 3.944706
## 6 5.633333 5.359069 6.942560 6.733842 7.490506 6.578878 7.976041 6.437220
## 430 431 432 433 434 435 436 437
## 1 8.696259 7.931573 8.088359 7.540841 8.039230 8.323316 8.488298 8.855936
## 2 4.134503 3.794201 3.973307 3.782250 3.619313 3.721287 3.748221 4.457023
## 3 7.717744 7.082043 7.134695 6.790664 7.058495 7.351287 7.386206 7.874780
## 4 5.654346 5.081922 5.298499 4.904392 5.104864 5.332295 5.460661 5.994414
## 5 4.007002 4.145470 4.267862 4.462911 4.105578 3.959357 3.969580 4.147301
## 6 6.946892 6.173374 6.398175 5.806166 6.272329 6.545788 6.747217 7.180959
## 438 439 440 441 442 443 444 445
## 1 9.396533 9.435637 8.099988 8.384080 7.713189 7.607664 7.769558 8.369895
## 2 4.811409 4.695929 2.433801 2.937692 2.207332 2.192461 2.239337 2.871156
## 3 8.394236 8.484083 7.006532 7.350912 6.477458 6.351316 6.518089 7.288150
## 4 6.386947 6.327543 4.552303 5.079909 4.380978 4.219854 4.422982 4.931360
## 5 4.213632 4.342741 4.516857 4.509393 4.608229 4.755074 4.637509 3.918161
## 6 7.707796 7.700430 6.054304 6.446442 5.755888 5.609025 5.811139 6.418899
## 446 447 448 449 450 451 452 453
## 1 8.869383 7.692356 7.719083 7.662880 7.734779 8.619425 7.510000 7.420544
## 2 4.315338 2.223077 2.207460 2.126064 2.281549 4.610171 2.238968 2.096565
## 3 7.822260 6.503523 6.592742 6.535974 6.588139 7.643669 6.322861 6.315283
## 4 5.892565 4.313539 4.358067 4.262430 4.358030 5.922856 4.230132 4.095576
## 5 4.052052 4.377493 4.626360 4.619462 4.290924 4.436440 4.659548 4.698128
## 6 7.168870 5.714462 5.725384 5.655226 5.767098 7.013088 5.561251 5.419305
## 454 455 456 457 458 459 460 461
## 1 7.488797 8.615112 8.280416 8.613939 8.529698 7.413953 7.197961 7.441333
## 2 2.816811 4.549028 4.088681 4.450875 4.516870 2.377775 2.175860 2.581875
## 3 6.201144 7.628370 7.338629 7.770650 7.771267 6.463171 6.189770 6.350729
## 4 4.575975 5.918794 5.464389 5.749648 5.801327 4.266589 4.034746 4.354303
## 5 5.115979 4.321729 4.205509 4.252759 4.258883 4.236988 4.789795 4.385829
## 6 5.704355 7.016989 6.589745 6.913673 6.866815 5.484535 5.216250 5.566897
## 462 463 464 465 466 467 468 469
## 1 7.224008 7.129990 7.081032 6.761263 6.784776 8.163381 7.276556 7.067634
## 2 2.197525 2.207914 2.436963 2.400811 2.744376 4.323182 2.345760 2.548814
## 3 6.150612 6.113243 6.000826 5.995825 6.265945 7.375314 6.308918 6.388907
## 4 4.028929 4.046035 4.100801 3.940852 4.014623 5.454107 3.942868 4.149291
## 5 4.871657 4.859767 5.057480 4.982831 4.910892 4.372635 4.541440 4.648344
## 6 5.245377 5.175440 5.168781 4.825356 4.830816 6.492417 5.264318 5.133202
## 470 471 472 473 474 475 476 477
## 1 6.854434 6.816620 6.708850 6.594683 6.547902 7.501061 7.637258 7.206421
## 2 2.734118 2.311425 2.560930 2.499788 3.048901 2.434451 2.523020 2.223730
## 3 6.323801 5.996607 5.921288 5.766964 5.546301 6.666256 6.654666 6.151680
## 4 4.089454 3.742729 3.729722 3.771861 4.165060 4.053967 4.237950 3.945356
## 5 4.973919 4.971853 5.181002 5.161492 5.472082 4.527575 4.374497 4.862825
## 6 4.901491 4.816208 4.722700 4.659061 4.806139 5.415982 5.640980 5.208138
## 478 479 480 481 482 483 484 485
## 1 8.130462 7.407656 7.165587 6.328683 6.331364 6.329978 6.225603 6.407568
## 2 2.819877 2.149619 2.407795 2.841677 3.062382 3.305435 3.354835 3.007909
## 3 7.232034 6.384794 6.121775 5.803910 5.637316 5.575392 6.127800 6.133862
## 4 4.658359 4.056417 4.119396 3.815854 3.967622 4.139027 4.014627 3.945221
## 5 4.341229 4.588992 4.776866 5.387882 5.594453 5.786301 5.679794 5.329406
## 6 6.105211 5.382604 5.214375 4.428172 4.526780 4.616956 4.359692 4.497564
## 486 487 488 489 490 491 492 493
## 1 6.249662 6.708037 6.500512 7.746032 8.298286 8.670417 7.692851 7.224881
## 2 2.935648 2.355052 2.761430 3.339171 3.627365 4.033745 3.245201 3.298803
## 3 5.880484 6.022019 6.037518 6.749983 7.341242 7.743312 6.605526 6.225869
## 4 3.898792 3.748954 3.856913 4.067660 4.515760 4.922601 4.029950 3.853652
## 5 5.440584 4.972136 5.232320 5.468533 5.317298 5.364747 5.458144 5.624994
## 6 4.392934 4.727043 4.539202 5.655817 6.220009 6.633606 5.634401 5.208921
## 494 495 496 497 498 499 500 501
## 1 5.413752 5.273091 5.426681 6.011801 5.542505 5.414893 5.810165 5.688309
## 2 3.852454 3.986370 4.203245 3.717331 3.612856 3.666547 3.612745 3.521661
## 3 4.881230 4.787928 5.205773 5.359640 4.929451 4.699697 5.121802 4.887289
## 4 2.137355 2.335780 2.705197 2.322917 1.885295 1.925584 2.012924 1.880862
## 5 5.924585 6.035621 6.099197 5.645035 5.731891 5.820200 5.672489 5.683894
## 6 2.874711 2.815571 3.076628 3.570270 2.982151 2.867755 3.260115 3.150398
## 502 503 504 505 506
## 1 5.506603 5.730311 5.775209 5.732539 5.991382
## 2 4.294822 4.194855 4.555464 4.415418 4.255945
## 3 4.737543 4.960431 4.668497 4.734780 5.374542
## 4 2.309307 2.174338 2.764118 2.545516 2.378712
## 5 6.417801 6.310447 6.682914 6.547413 6.324684
## 6 3.056424 3.190441 3.518096 3.391335 3.469554
##
## $totss
## [1] 748534.8
##
## $withinss
## [1] 17974.37 26811.41 21548.41 22667.20 55771.90 25160.33
##
## $tot.withinss
## [1] 169933.6
##
## $betweenss
## [1] 578601.2
myclust<-data.frame(km_bs2$cluster)
boston_scaled2$clust<-km_bs2$cluster
head(boston_scaled2)
## crim zn indus chas nox rm
## 1 -0.4193669 0.2845483 -1.2866362 -0.2723291 -0.1440749 0.4132629
## 2 -0.4169267 -0.4872402 -0.5927944 -0.2723291 -0.7395304 0.1940824
## 3 -0.4169290 -0.4872402 -0.5927944 -0.2723291 -0.7395304 1.2814456
## 4 -0.4163384 -0.4872402 -1.3055857 -0.2723291 -0.8344581 1.0152978
## 5 -0.4120741 -0.4872402 -1.3055857 -0.2723291 -0.8344581 1.2273620
## 6 -0.4166314 -0.4872402 -1.3055857 -0.2723291 -0.8344581 0.2068916
## age dis rad tax ptratio black
## 1 -0.1198948 0.140075 -0.9818712 -0.6659492 -1.4575580 0.4406159
## 2 0.3668034 0.556609 -0.8670245 -0.9863534 -0.3027945 0.4406159
## 3 -0.2655490 0.556609 -0.8670245 -0.9863534 -0.3027945 0.3960351
## 4 -0.8090878 1.076671 -0.7521778 -1.1050216 0.1129203 0.4157514
## 5 -0.5106743 1.076671 -0.7521778 -1.1050216 0.1129203 0.4406159
## 6 -0.3508100 1.076671 -0.7521778 -1.1050216 0.1129203 0.4101651
## lstat medv clust
## 1 -1.0744990 0.1595278 6
## 2 -0.4919525 -0.1014239 6
## 3 -1.2075324 1.3229375 6
## 4 -1.3601708 1.1815886 6
## 5 -1.0254866 1.4860323 6
## 6 -1.0422909 0.6705582 6
lda.fit_bs2<-lda(clust~., data = boston_scaled2 )
lda.fit_bs2
## Call:
## lda(clust ~ ., data = boston_scaled2)
##
## Prior probabilities of groups:
## 1 2 3 4 5 6
## 0.10079051 0.19960474 0.09486166 0.20553360 0.12845850 0.27075099
##
## Group means:
## crim zn indus chas nox rm
## 1 -0.4149170 2.55535505 -1.228758914 -0.1951310 -1.21919439 0.78676843
## 2 0.3880377 -0.48724019 1.165421314 -0.2723291 0.98659851 -0.28553884
## 3 -0.3613809 -0.09419977 -0.474086929 1.5321752 -0.12487357 1.27068222
## 4 -0.3580718 -0.46023584 -0.003188584 -0.2723291 -0.09478548 -0.35414265
## 5 1.4172264 -0.48724019 1.069802298 0.4545202 1.34622349 -0.73713928
## 6 -0.4055840 0.02149547 -0.740804469 -0.2723291 -0.79649957 0.09099544
## age dis rad tax ptratio black
## 1 -1.4488239 1.7464736 -0.7048880 -0.5692695 -0.8353442 0.34924852
## 2 0.7651453 -0.7898745 1.1388129 1.2431405 0.6932747 0.04498348
## 3 0.2307707 -0.3386056 -0.4961654 -0.7220694 -1.1226766 0.32813467
## 4 0.4093998 -0.2612071 -0.5865335 -0.4342609 0.2608189 0.19191309
## 5 0.8557425 -0.9615698 1.2885597 1.2934457 0.4142248 -1.68787016
## 6 -0.8223904 0.7053125 -0.5694290 -0.7355910 -0.2013102 0.37698635
## lstat medv
## 1 -0.9773530 0.8760790
## 2 0.6734731 -0.5987824
## 3 -0.6138415 1.4407282
## 4 0.1508360 -0.2838601
## 5 1.1961180 -0.8078336
## 6 -0.5996059 0.2092896
##
## Coefficients of linear discriminants:
## LD1 LD2 LD3 LD4 LD5
## crim 0.04811996 -0.28556378 -0.55488255 0.49400398 0.05329096
## zn -0.13738829 -1.83004313 0.34546140 -0.26802062 -0.87758918
## indus 0.74925386 -0.10015651 0.61607026 -0.42031079 0.25109137
## chas 0.13287282 -0.13228082 -0.94523359 -0.16829634 0.04786106
## nox 1.21764057 -0.81216848 -0.12506389 0.27633410 0.13213424
## rm -0.12060003 -0.04058521 -0.02502279 -0.75468374 0.21331834
## age 0.17397462 0.34382124 -0.07430813 -0.37956005 -0.95205471
## dis -0.36273454 -0.54652248 0.11546588 0.26210162 0.59195828
## rad 0.61453519 0.40958433 0.29006265 -0.40963042 1.56473994
## tax 0.75124298 -1.03741454 0.22707980 -0.17126395 -0.61781814
## ptratio 0.36217649 -0.18603253 0.30060517 0.16017164 -0.53729844
## black -0.27542772 0.27016025 0.77143821 -0.87012879 0.23445845
## lstat 0.48988940 -0.40861927 -0.53017288 -0.23295699 -0.06758426
## medv 0.22977036 -0.57759705 -0.86635437 -0.06977308 -0.10361245
##
## Proportion of trace:
## LD1 LD2 LD3 LD4 LD5
## 0.7285 0.1498 0.0750 0.0298 0.0168
lda.arrows <- function(x, myscale = 1, arrow_heads = 0.1, color = "red", tex = 0.75, choices = c(1,2)){
heads <- coef(x)
arrows(x0 = 0, y0 = 0,
x1 = myscale * heads[,choices[1]],
y1 = myscale * heads[,choices[2]], col=color, length = arrow_heads)
text(myscale * heads[,choices], labels = row.names(heads),
cex = tex, col=color, pos=3)
}
plot(lda.fit_bs2, dimen = 2)
lda.arrows(lda.fit_bs2, myscale = 3)
I think the dataset could be grouped more easily by a lower number of clusters, though I’m not sure what would be the minimum number. The top three most relevant variables according to our bi-plot are “zn”, “nox”, and “tax”.
Super.Bonus
Additional ways for visualising LDA:
library(plotly)
##
## Attaching package: 'plotly'
## The following object is masked from 'package:MASS':
##
## select
## The following object is masked from 'package:ggplot2':
##
## last_plot
## The following object is masked from 'package:stats':
##
## filter
## The following object is masked from 'package:graphics':
##
## layout
model_predictors <- dplyr::select(train, -crime)
dim(model_predictors)
## [1] 404 13
dim(lda.fit$scaling)
## [1] 13 3
matrix_product <- as.matrix(model_predictors) %*% lda.fit$scaling
matrix_product <- as.data.frame(matrix_product)
plot_ly(x = matrix_product$LD1, y = matrix_product$LD2, z = matrix_product$LD3, type= 'scatter3d', mode='markers', color = train$crim)
k_means_matpro <- kmeans(matrix_product, centers = 6, iter.max = 10, nstart = 1, trace=FALSE)
head(train)
## zn indus chas nox rm age
## 8 0.04872402 -0.4761823 -0.2723291 -0.2648919 -0.1603069 0.9778406
## 18 -0.48724019 -0.4368257 -0.2723291 -0.1440749 -0.4193385 0.4662746
## 440 -0.48724019 1.0149946 -0.2723291 1.5991427 -0.9359783 0.8996847
## 179 -0.48724019 -1.0330050 -0.2723291 -0.3857090 0.8188892 0.2069391
## 224 -0.48724019 -0.7196100 -0.2723291 -0.4115983 0.4744627 0.4343017
## 21 -0.48724019 -0.4368257 -0.2723291 -0.1440749 -1.0171035 1.0488914
## dis rad tax ptratio black lstat
## 8 1.023624897 -0.5224844 -0.5769480 -1.5037485 0.4406159 0.9097999
## 18 0.219810555 -0.6373311 -0.6006817 1.1753027 0.3294377 0.2824421
## 440 -0.939275859 1.6596029 1.5294129 0.8057784 0.4406159 1.4321312
## 179 -0.417789076 -0.5224844 -0.6659492 -0.8570810 0.3789476 -0.8028307
## 224 -0.248345051 -0.1779443 -0.6006817 -0.4875567 0.4406159 -0.7076067
## 21 0.001356935 -0.6373311 -0.6006817 1.1753027 0.2179309 1.1716657
## medv crime
## 8 0.4965904 med_low
## 18 -0.5472164 med_high
## 440 -1.0582468 high
## 179 0.8010341 low
## 224 0.8227800 med_high
## 21 -0.9712629 med_high
myclust <- NA
train$cl<-myclust
boston_scaled2$cl<-myclust
head(boston_scaled2)
## crim zn indus chas nox rm
## 1 -0.4193669 0.2845483 -1.2866362 -0.2723291 -0.1440749 0.4132629
## 2 -0.4169267 -0.4872402 -0.5927944 -0.2723291 -0.7395304 0.1940824
## 3 -0.4169290 -0.4872402 -0.5927944 -0.2723291 -0.7395304 1.2814456
## 4 -0.4163384 -0.4872402 -1.3055857 -0.2723291 -0.8344581 1.0152978
## 5 -0.4120741 -0.4872402 -1.3055857 -0.2723291 -0.8344581 1.2273620
## 6 -0.4166314 -0.4872402 -1.3055857 -0.2723291 -0.8344581 0.2068916
## age dis rad tax ptratio black
## 1 -0.1198948 0.140075 -0.9818712 -0.6659492 -1.4575580 0.4406159
## 2 0.3668034 0.556609 -0.8670245 -0.9863534 -0.3027945 0.4406159
## 3 -0.2655490 0.556609 -0.8670245 -0.9863534 -0.3027945 0.3960351
## 4 -0.8090878 1.076671 -0.7521778 -1.1050216 0.1129203 0.4157514
## 5 -0.5106743 1.076671 -0.7521778 -1.1050216 0.1129203 0.4406159
## 6 -0.3508100 1.076671 -0.7521778 -1.1050216 0.1129203 0.4101651
## lstat medv clust cl
## 1 -1.0744990 0.1595278 6 NA
## 2 -0.4919525 -0.1014239 6 NA
## 3 -1.2075324 1.3229375 6 NA
## 4 -1.3601708 1.1815886 6 NA
## 5 -1.0254866 1.4860323 6 NA
## 6 -1.0422909 0.6705582 6 NA
head(train)
## zn indus chas nox rm age
## 8 0.04872402 -0.4761823 -0.2723291 -0.2648919 -0.1603069 0.9778406
## 18 -0.48724019 -0.4368257 -0.2723291 -0.1440749 -0.4193385 0.4662746
## 440 -0.48724019 1.0149946 -0.2723291 1.5991427 -0.9359783 0.8996847
## 179 -0.48724019 -1.0330050 -0.2723291 -0.3857090 0.8188892 0.2069391
## 224 -0.48724019 -0.7196100 -0.2723291 -0.4115983 0.4744627 0.4343017
## 21 -0.48724019 -0.4368257 -0.2723291 -0.1440749 -1.0171035 1.0488914
## dis rad tax ptratio black lstat
## 8 1.023624897 -0.5224844 -0.5769480 -1.5037485 0.4406159 0.9097999
## 18 0.219810555 -0.6373311 -0.6006817 1.1753027 0.3294377 0.2824421
## 440 -0.939275859 1.6596029 1.5294129 0.8057784 0.4406159 1.4321312
## 179 -0.417789076 -0.5224844 -0.6659492 -0.8570810 0.3789476 -0.8028307
## 224 -0.248345051 -0.1779443 -0.6006817 -0.4875567 0.4406159 -0.7076067
## 21 0.001356935 -0.6373311 -0.6006817 1.1753027 0.2179309 1.1716657
## medv crime cl
## 8 0.4965904 med_low NA
## 18 -0.5472164 med_high NA
## 440 -1.0582468 high NA
## 179 0.8010341 low NA
## 224 0.8227800 med_high NA
## 21 -0.9712629 med_high NA
rownames(train)
## [1] "8" "18" "440" "179" "224" "21" "229" "71" "394" "499" "457"
## [12] "280" "497" "230" "261" "111" "114" "139" "371" "462" "110" "51"
## [23] "84" "355" "56" "402" "163" "160" "375" "380" "134" "342" "39"
## [34] "251" "399" "279" "16" "149" "30" "276" "319" "483" "52" "327"
## [45] "212" "417" "215" "91" "299" "401" "310" "1" "368" "195" "373"
## [56] "10" "225" "335" "284" "79" "46" "256" "211" "35" "217" "153"
## [67] "61" "392" "473" "386" "361" "389" "267" "421" "374" "325" "68"
## [78] "158" "259" "372" "362" "89" "44" "186" "167" "15" "291" "318"
## [89] "162" "336" "201" "311" "136" "416" "32" "365" "469" "182" "455"
## [100] "37" "409" "308" "333" "33" "410" "2" "282" "296" "262" "366"
## [111] "405" "425" "250" "154" "188" "27" "175" "467" "312" "385" "378"
## [122] "475" "144" "353" "14" "315" "28" "231" "94" "400" "194" "437"
## [133] "383" "65" "431" "324" "206" "13" "426" "26" "209" "45" "492"
## [144] "270" "301" "493" "438" "292" "357" "432" "193" "210" "278" "119"
## [155] "439" "97" "42" "424" "300" "203" "283" "364" "286" "22" "19"
## [166] "219" "17" "101" "130" "450" "487" "135" "322" "208" "258" "132"
## [177] "146" "72" "264" "12" "360" "430" "266" "161" "288" "448" "145"
## [188] "108" "484" "113" "220" "129" "289" "64" "459" "140" "235" "81"
## [199] "408" "506" "200" "115" "62" "307" "480" "3" "321" "491" "348"
## [210] "446" "494" "419" "147" "379" "341" "471" "74" "428" "174" "171"
## [221] "59" "302" "246" "36" "98" "7" "486" "92" "169" "157" "31"
## [232] "350" "60" "38" "96" "382" "498" "303" "456" "138" "464" "297"
## [243] "472" "67" "232" "398" "55" "173" "465" "482" "198" "124" "463"
## [254] "189" "5" "323" "265" "466" "352" "236" "127" "314" "155" "125"
## [265] "90" "131" "120" "99" "249" "58" "502" "451" "433" "100" "435"
## [276] "304" "197" "415" "434" "86" "414" "346" "343" "137" "218" "269"
## [287] "70" "126" "504" "404" "180" "20" "345" "391" "349" "287" "170"
## [298] "82" "29" "306" "199" "501" "23" "128" "331" "238" "260" "293"
## [309] "239" "505" "73" "106" "290" "452" "285" "326" "223" "222" "244"
## [320] "441" "168" "309" "485" "257" "148" "429" "234" "445" "103" "458"
## [331] "344" "329" "330" "165" "75" "240" "274" "102" "87" "247" "48"
## [342] "252" "226" "347" "34" "328" "453" "88" "228" "109" "143" "118"
## [353] "481" "423" "476" "436" "388" "123" "305" "340" "241" "317" "181"
## [364] "9" "242" "489" "150" "367" "363" "477" "183" "24" "243" "172"
## [375] "185" "496" "376" "104" "263" "254" "11" "478" "447" "77" "387"
## [386] "207" "177" "381" "403" "245" "191" "105" "449" "271" "63" "57"
## [397] "406" "184" "25" "474" "334" "54" "339" "83"
rownames(boston_scaled2)
## [1] "1" "2" "3" "4" "5" "6" "7" "8" "9" "10" "11"
## [12] "12" "13" "14" "15" "16" "17" "18" "19" "20" "21" "22"
## [23] "23" "24" "25" "26" "27" "28" "29" "30" "31" "32" "33"
## [34] "34" "35" "36" "37" "38" "39" "40" "41" "42" "43" "44"
## [45] "45" "46" "47" "48" "49" "50" "51" "52" "53" "54" "55"
## [56] "56" "57" "58" "59" "60" "61" "62" "63" "64" "65" "66"
## [67] "67" "68" "69" "70" "71" "72" "73" "74" "75" "76" "77"
## [78] "78" "79" "80" "81" "82" "83" "84" "85" "86" "87" "88"
## [89] "89" "90" "91" "92" "93" "94" "95" "96" "97" "98" "99"
## [100] "100" "101" "102" "103" "104" "105" "106" "107" "108" "109" "110"
## [111] "111" "112" "113" "114" "115" "116" "117" "118" "119" "120" "121"
## [122] "122" "123" "124" "125" "126" "127" "128" "129" "130" "131" "132"
## [133] "133" "134" "135" "136" "137" "138" "139" "140" "141" "142" "143"
## [144] "144" "145" "146" "147" "148" "149" "150" "151" "152" "153" "154"
## [155] "155" "156" "157" "158" "159" "160" "161" "162" "163" "164" "165"
## [166] "166" "167" "168" "169" "170" "171" "172" "173" "174" "175" "176"
## [177] "177" "178" "179" "180" "181" "182" "183" "184" "185" "186" "187"
## [188] "188" "189" "190" "191" "192" "193" "194" "195" "196" "197" "198"
## [199] "199" "200" "201" "202" "203" "204" "205" "206" "207" "208" "209"
## [210] "210" "211" "212" "213" "214" "215" "216" "217" "218" "219" "220"
## [221] "221" "222" "223" "224" "225" "226" "227" "228" "229" "230" "231"
## [232] "232" "233" "234" "235" "236" "237" "238" "239" "240" "241" "242"
## [243] "243" "244" "245" "246" "247" "248" "249" "250" "251" "252" "253"
## [254] "254" "255" "256" "257" "258" "259" "260" "261" "262" "263" "264"
## [265] "265" "266" "267" "268" "269" "270" "271" "272" "273" "274" "275"
## [276] "276" "277" "278" "279" "280" "281" "282" "283" "284" "285" "286"
## [287] "287" "288" "289" "290" "291" "292" "293" "294" "295" "296" "297"
## [298] "298" "299" "300" "301" "302" "303" "304" "305" "306" "307" "308"
## [309] "309" "310" "311" "312" "313" "314" "315" "316" "317" "318" "319"
## [320] "320" "321" "322" "323" "324" "325" "326" "327" "328" "329" "330"
## [331] "331" "332" "333" "334" "335" "336" "337" "338" "339" "340" "341"
## [342] "342" "343" "344" "345" "346" "347" "348" "349" "350" "351" "352"
## [353] "353" "354" "355" "356" "357" "358" "359" "360" "361" "362" "363"
## [364] "364" "365" "366" "367" "368" "369" "370" "371" "372" "373" "374"
## [375] "375" "376" "377" "378" "379" "380" "381" "382" "383" "384" "385"
## [386] "386" "387" "388" "389" "390" "391" "392" "393" "394" "395" "396"
## [397] "397" "398" "399" "400" "401" "402" "403" "404" "405" "406" "407"
## [408] "408" "409" "410" "411" "412" "413" "414" "415" "416" "417" "418"
## [419] "419" "420" "421" "422" "423" "424" "425" "426" "427" "428" "429"
## [430] "430" "431" "432" "433" "434" "435" "436" "437" "438" "439" "440"
## [441] "441" "442" "443" "444" "445" "446" "447" "448" "449" "450" "451"
## [452] "452" "453" "454" "455" "456" "457" "458" "459" "460" "461" "462"
## [463] "463" "464" "465" "466" "467" "468" "469" "470" "471" "472" "473"
## [474] "474" "475" "476" "477" "478" "479" "480" "481" "482" "483" "484"
## [485] "485" "486" "487" "488" "489" "490" "491" "492" "493" "494" "495"
## [496] "496" "497" "498" "499" "500" "501" "502" "503" "504" "505" "506"
train$cl <- boston_scaled2$clust[match(rownames(train), rownames(boston_scaled2))]
head(train)
## zn indus chas nox rm age
## 8 0.04872402 -0.4761823 -0.2723291 -0.2648919 -0.1603069 0.9778406
## 18 -0.48724019 -0.4368257 -0.2723291 -0.1440749 -0.4193385 0.4662746
## 440 -0.48724019 1.0149946 -0.2723291 1.5991427 -0.9359783 0.8996847
## 179 -0.48724019 -1.0330050 -0.2723291 -0.3857090 0.8188892 0.2069391
## 224 -0.48724019 -0.7196100 -0.2723291 -0.4115983 0.4744627 0.4343017
## 21 -0.48724019 -0.4368257 -0.2723291 -0.1440749 -1.0171035 1.0488914
## dis rad tax ptratio black lstat
## 8 1.023624897 -0.5224844 -0.5769480 -1.5037485 0.4406159 0.9097999
## 18 0.219810555 -0.6373311 -0.6006817 1.1753027 0.3294377 0.2824421
## 440 -0.939275859 1.6596029 1.5294129 0.8057784 0.4406159 1.4321312
## 179 -0.417789076 -0.5224844 -0.6659492 -0.8570810 0.3789476 -0.8028307
## 224 -0.248345051 -0.1779443 -0.6006817 -0.4875567 0.4406159 -0.7076067
## 21 0.001356935 -0.6373311 -0.6006817 1.1753027 0.2179309 1.1716657
## medv crime cl
## 8 0.4965904 med_low 4
## 18 -0.5472164 med_high 4
## 440 -1.0582468 high 2
## 179 0.8010341 low 6
## 224 0.8227800 med_high 6
## 21 -0.9712629 med_high 4
nrow(train)
## [1] 404
plot_ly(x = matrix_product$LD1, y = matrix_product$LD2, z = matrix_product$LD3, type = "scatter3d", mode="markers", color = train$cl)
In light of my research, clustering made with K-means have turned out to be more informative than thes one based on crime classes.